Display device that switches light emission states multiple times during one field period

ABSTRACT

A scan driving circuit includes a shift register unit and a logic circuit unit. The start of a start pulse of an output signal ST p+1  of a p+1′th shift register is situated between the start and end of a start pulse of the output signal ST p  of a p′th shift register, and one each of a first enable signal through a Q′th enable signal exist in sequence between the start of the start pulse of the output signal ST p  and the start of the start pulse of the output signal ST p+1 . The operations of a (p′, q)′th NAND circuit are restricted based on period identifying signals, such that the NAND circuit generates scanning signals based only on a portion of the output signal ST p  corresponding to the first start pulse, the signal obtained by inverting the output signal ST p+1 , and the q′th enable signal EN q .

CROSS REFERENCES TO RELATED APPLICATIONS

This is a Continuation Application of patent application Ser. No. 14/297,859, filed Jun. 6, 2014, which is a Continuation Application of patent application Ser. No. 13/867,670, filed Apr. 22, 2013, now U.S. Pat. No. 8,797,241, issued on Aug. 5, 2014, which is a Continuation Application of patent application Ser. No. 12/457,756, filed Jun. 19, 2009, now U.S. Pat. No. 8,427,458, issued on Apr. 23, 2013, which claims priority from Japanese Patent Application No.: 2008-182369 filed in the Japanese Patent Office on Jul. 14, 2008, the entire contents of which being incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a scan driving circuit and to a display device including the scan driving circuit. More particularly, the present invention relates to a scan driving circuit and to a display device including the scan driving circuit, in which signals can be supplied to scanning lines, initialization control lines, and display control lines, and a lit/unlit state of display elements can be switched multiple times during one field period by supplying multiple pulse signals to the display control lines during the field period, without affecting the signals being supplied to the scanning lines and initialization control lines.

2. Description of the Related Art

Examples of widely used display devices having display elements arranged in the form of a two-dimensional matrix include liquid crystal display devices made up of liquid crystal cells driven by voltage, and also display devices including light emitting units which emit light under application of electric current (e.g., organic electroluminescence light emitting units) and driving circuits for driving the light emitting units.

The luminance of display elements including light emitting units which emit light under application of electric current is controlled by the value of the current flowing through the light emitting units. In the same way as with liquid crystal display devices, such display devices having these display elements (e.g., organic electroluminescence display devices) can be driven by the simple matrix method and the active matrix method. While the active matrix method has shortcomings such as greater complexity in structure as compared with the simple matrix method, there are also various advantages, such as being capable of higher luminance.

Various types of driving circuits configured from transistors and capacitance units are in widespread use as circuits for driving a light emitting unit by the active matrix method. For example, Japanese Unexamined Patent Application Publication No. 2005-31630 discloses a display element configured of an organic electroluminescence light emitting unit and a driving circuit, and a driving method thereof. This driving circuit is a driving circuit configured of six transistors and one capacitance unit (hereinafter referred to as “6Tr/1C driving circuit”). FIG. 26 illustrates an equivalent circuit to a driving circuit (6Tr/1C driving circuit) of a display element of the m′th row and n′th column in a display device configured of display elements arrayed in the form of a two-dimensional matrix. Note that in the description, the display elements are assumed to be scanned in line sequence.

The 6Tr/1C driving circuit has a write transistor TR_(W), a driving transistor TR_(D), a capacitance unit C₁, and also a first transistor TR₁, a second transistor TR₂, a third transistor TR₃, and a fourth transistor TR₄.

At the write transistor TR_(W), one source/drain region is connected to a data line DTL_(n), and the gate electrode is connected to a scanning line SCL_(m). At the driving transistor TR_(D), one source/drain region is connected to the other source/drain region of the write transistor TR_(W), thereby configuring a first node ND₁. One end of the capacitance unit C₁ is connected to a power supply line PS₁. At the capacitance unit C₁, a predetermined reference voltage (later-described voltage V_(CC) in the example shown in FIG. 26) is applied to one end, and the other end is connected to the gate electrode of the driving transistor TR_(D), thereby configuring a second node ND₂. The scanning line SCL_(m) is connected to an unshown scanning circuit, and the data line DTL_(n) is connected to a signal output circuit 100.

At the first transistor TR₁, one source/drain region is connected to the second node ND₂, and the other source/drain region is connected to the other source/drain region of the driving transistor TR_(D). The first transistor TR₁ makes up a switch circuit portion connected between the second node ND₂ and the other source/drain region of the driving transistor TR_(D).

At the second transistor TR₂, one source/drain region is connected to a power supply line PS₃ to which is applied a predetermined initializing voltage V_(Ini) (e.g., −4 volts) for initialization of the potential of the second node ND₂, and the other source/drain region is connected to the second node ND₂. The second transistor TR₂ makes TR₁ makes up a switch circuit portion connected between the second node ND₂ and the power supply line PS₃ to which is applied the predetermined initializing voltage V_(Ini).

At the third transistor TR₃, one source/drain region is connected to a power supply line PS₁ to which is applied a predetermined driving voltage V_(CC) (e.g., 10 volts), and the other source/drain region is connected to the first node ND₁. The third transistor TR₃ makes up a switch circuit portion connected between the first node ND₁ and the power supply line PS₁ to which is applied the predetermined driving voltage V_(CC).

At the fourth transistor TR₄, one source/drain region is connected to the other source/drain region of the driving transistor TR_(D), and the other source/drain region is connected to one end of a light emitting unit ELP (more specifically, the anode electrode of the light emitting unit ELP). The fourth transistor TR₄ makes up a switch circuit portion connected between the other source/drain region of the driving transistor TR_(D) and one end of the light emitting unit ELP.

The gate electrode of the write transistor TR_(W) and the gate electrode of the first transistor TR₁ are connected to the scanning line SCL_(m). The gate electrode of the second transistor TR₂ is connected to an initialization control line AZ_(m). Scanning signal supplied to an unshown scanning line SCL_(m-1) scanned immediately prior to the scanning line SCL_(m) is also supplied to the initialization control line AZ_(m). The gate electrodes of the third transistor TR₃ and the fourth transistor TR₄ are connected to a display control line CL_(m) for controlling the lit/unlit state of the display element.

For example, each transistor is formed as a p-channel thin-film transistor (TFT), with the light emitting unit ELP provided on an interlayer-insulating later or the like, formed so as to cover the driving circuit. At the light emitting unit ELP, the anode electrode is connected to the other source/drain region of the fourth transistor TR₄, and the cathode electrode is connected to a power supply line PS₂. Voltage V_(cat) (e.g., −10 volts) is applied to the cathode electrode of the light emitting unit ELP. Symbol C_(EL) represents the capacitance of the light emitting unit ELP.

Now, when configuring transistors of TFTs, irregularity in threshold voltage is unavoidable to a certain extent. In the event that there is irregularity in the amount of current flowing through the light emitting unit ELP due to irregularity in the threshold value of the driving transistor TR_(D), the uniformity of luminance of the display device suffers. Accordingly, an arrangement has to be made where the amount of current flowing through the light emitting unit ELP is not affected by irregularity in the threshold value of the driving transistor TR_(D). As described later, the light emitting unit ELP is driven so as to be unaffected by irregularity in the threshold value of the driving transistor TR_(D).

A driving method of a display element at the m′th row and n′th column of a display device configured as a two-dimensional array of N×M display elements will be described with reference to FIGS. 27A and 27B. FIG. 27A illustrates a schematic timing chart of signals on the initialization control line AZ_(m), scanning line SCL_(m), and display control line CL_(m). FIGS. 27B through 28B schematically illustrate the on/off states and the likes of the transistors of a 6Tr/1C driving circuit. To facilitate description, we will refer the period during which the initialization control line AZ_(m) is scanned as the “m−1′th horizontal scan period”, and the period during which the scanning line SCL_(m) is scanned as the “m′th horizontal scan period”.

As shown in FIG. 27A, in the m−1′th horizontal scan period, an initialization process is carried out, which will be described in detail with reference to FIG. 27B. In the m−1′th horizontal scan period, the initialization control line AZ_(m) goes from a high level to a low level, and the display control line CL_(m) goes from a low level to a high level. Note that the scanning line SCL_(m) remains at the high level. Accordingly, during the m−1′th horizontal scan period, the write transistor TR_(W), first transistor TR₁, third transistor TR₃, and fourth transistor TR₄ are in an off state, while the second transistor TR₂ is in an on state.

A predetermined initialization voltage V_(Ini) for initializing the potential of the second node ND₂ is applied to the second node ND₂ via the second transistor TR₂ which is in the on state. Accordingly, the potential of the second node ND₂ is initialized.

Next, as shown in FIG. 27A, a video signal V_(Sig) is written in the m′th horizontal scanning period. At this time, threshold voltage canceling processing of the driving transistor TR_(D) is performed in conjunction. Specifically, the second node ND₂ and the other source/drain region of the driving transistor TR_(D) are electrically connected, the video signal V_(Sig) is applied from the data line DTL_(n) to the first node ND₁ via the write transistor TR_(W) which has been placed in an on state due to the signal from the scanning line SCL_(m), thereby changing the potential of the second node ND₂ toward a potential which can be calculated by subtracting the threshold voltage V_(th) of the driving transistor TR_(D) from the video signal V_(Sig).

More detailed description will be made with reference to FIGS. 27A and 28A. In the m′th horizontal scanning period, the initialization control line AZ_(m) goes from a low level to a high level, and the scanning line SCL_(m) goes from a high level to a low level. Note that the display control line CL_(m) remains at the high level. Accordingly, at the m′th horizontal scanning period, the write transistor TR_(W) and first transistor TR₁ are in an on state, while the second transistor TR₂, third transistor TR₃, and fourth transistor TR₄ are in an off state.

The second node ND₂ and the other source/drain region of the driving transistor TR_(D) are electrically connected via the first transistor TR₁ which is in an on state, and the video signal V_(Sig) from the data line DT_(n) is applied to the first node ND₁ via the write transistor TR_(W) which is in an on state due to the signal from the scanning line SCL_(m). Accordingly, the potential of the second node ND₂ changes toward a voltage which can be calculated by subtracting the threshold voltage V_(th) of the driving transistor TR_(D) from the video signal V_(Sig).

According to the above-described initialization process, if the potential of the second node ND₂ has been initialized such that the driving transistor TR_(D) is in an on state at the start of the m′th horizontal scanning period, the potential of the second node ND₂ changes toward the potential of the video signal V_(Sig) which is applied to the first node ND₁. However, once the potential difference between the gate electrode of the driving transistor TR_(D) and one source/drain region thereof reaches V_(th), the driving transistor TR_(D) goes to an off state. In this state, the potential of the second node ND₂ is approximately (V_(Sig)−V_(th)).

Next, the light emitting unit ELP is driven by applying current to the light emitting unit ELP via the driving transistor TR_(D).

More detailed description will be made with reference to FIGS. 27A and 28B. At the end of the m′th horizontal scanning period, the scanning line SCL_(m) goes from a low level to a high level. Also, the display control line CL_(m) goes from a high level to a low level. Note that the initialization control line AZ_(m) remains at the high level. The third transistor TR₃ and fourth transistor TR₄ are in an on state, while the write transistor TR_(W), first transistor TR₁, and second transistor TR₂ are in an off state.

Driving voltage V_(CC) is applied to one source/drain region of the driving transistor TR_(D) via the third transistor TR₃ which is in an on state. Also, the other source/drain region of the driving transistor TR_(D) and one end of the light emitting unit ELP are connected via the fourth transistor TR₄ which is in an on state.

The current flowing through the light emitting unit ELP is a drain current I_(ds) which flows from the source region of the driving transistor TR_(D) to the drain region thereof, so this can be expressed with the following expression (A) assuming that the driving transistor TR_(D) operates ideally at the saturation region. As shown in FIG. 28B, the drain current I_(ds) is applied to the light emitting unit ELP, and the light emitting unit ELP emits light at a luminance corresponding to the value of the drain current I_(ds).

I _(ds) =k·μ·(V _(gs)-V _(th))²  (A)

where μ represents effective mobility, L represents channel length, W represents channel width, V_(gs) represents voltage between the source region and gate region of the driving transistor TR_(D), and C_(ox) represents

(relative permittivity of gate insulation layer)×(permittivity of vacuum)/(thickness of gate insulation layer)

in

k=(1/2)·(W/L)·C _(ox).

Further, since

V _(gs) ≈V _(CC)−(V _(Sig) −V _(th))  (B)

holds, the above Expression (A) can be rewritten as follows.

I _(ds) =k·μ·(V _(CC)−(V _(Sig) −V _(th))−V _(th))² =k·μ·(V _(CC) −V _(Sig))²  (C)

As can be clearly understood from the above Expression (C), the threshold voltage V_(th) of the driving transistor TR_(D) has no bearing on the value of the drain current I_(ds). In other words, a drain current I_(ds) corresponding to the video signal V_(Sig) can be applied to the light emitting unit ELP unaffected by the value of the threshold voltage V_(th) of the driving transistor TR_(D). With the above-described driving method, irregularities in the threshold voltage V_(th) of the driving transistor TR_(D) do not affect the luminance of the display element.

SUMMARY OF THE INVENTION

For a display device having the above-described display elements to operate, circuits have to be provided which supply signals to the scanning lines, initialization control lines, and display control lines. The circuits for supplying these signals are preferably circuits of an integrated structure, from the perspective of reduction in layout area of the circuits, and reduction of circuit costs. Also, enabling multiple pulse signals to be supplied to the display control lines within one field circuit without affecting the signals supplied to the scanning lines and initialization control lines is preferable from the perspective of reducing flickering of the image displayed on the display device.

It has been found desirable to provide a scan driving circuit capable of supplying signals to the scanning lines, initialization control lines, and display control lines, and capable of supplying multiple pulse signals to the display control lines within one field circuit without affecting the signals supplied to the scanning lines and initialization control lines.

A display device according to an embodiment of the present invention includes:

(1) display elements arrayed in the form of a two-dimensional matrix;

(2) scanning lines, initialization control lines configured to initialize the display elements, and display control lines configured to control lit/unlit states of the display elements, the scanning lines, initialization control lines, and display control lines extending in a first direction;

(3) data lines extending in a second direction different from the first direction; and

(4) a scan driving circuit.

A scan driving circuit according to the present invention, and also configuring the display device according to the present invention, includes:

(A) a shift register unit configured of P (wherein P is a natural number of 3 or greater) stages of shift registers, to sequentially shift input start pulses and output output signals from each stage, and

(B) a logic circuit unit configured to operate based on output signals from the shift register unit, and enable signals,

(C) where, with the output signals of a p′th (where p=1, 2, . . . P−1) stage shift register represented as ST_(p), the start of a start pulse of an output signal ST_(p+1) of a p+1′th shift register is situated between the start and end of a start pulse of the output signal ST_(p),

(D) and where one each of a first enable signal through a Q′th enable signal (where Q is a natural number of 2 or greater) exist in sequence between the start of the start pulse of the output signal ST_(p) and the start of the start pulse of the output signal ST_(p+1),

(E) and wherein the logic circuit unit includes (P−2)×Q NAND circuits;

wherein a first start pulse through a U′th (where U is a natural number of 2 or greater) start pulse are input to a first stage shift register during a period equivalent to one field period;

and wherein period identifying signals are input to the logic circuit unit to identify each period from a u′th (where u=1, 2, . . . U−1) start pulse in an output signal ST₁ to a u+1′th start pulse, and a period from the start of the U′th start pulse to the start of the first start pulse in the next frame;

and wherein, with a q′th enable signal (where q=1, 2, . . . Q−1) represented as EN_(q), a signal based on a period identifying signal, the output signal ST_(p), a signal obtained by inverting the output signal ST_(p+1), and the q′th enable signal EN_(q), are input to a (p′, q)′th NAND circuit;

and wherein the operations of the NAND circuit are restricted based on period identifying signals, such that the NAND circuit generates scanning signals based only on a portion of the output signal ST_(p) corresponding to the first start pulse, the signal obtained by inverting the output signal ST_(p+1), and the q′th enable signal EN_(q).

With the display device according to an embodiment of the present invention, with regard to a display element receiving supply of signals based on scanning signals from the (p′, q)′th NAND circuit (except for a case wherein (p′=1, q=1) via a scanning line,

a signal based on a scanning signal from a (p′−1, q′)′th NAND circuit in the event that q=1 holds, and a signal based on a scanning signal from a (p′, q″)′th (wherein q″ is a natural number from 1 through (q−1)) NAND circuit in the event that q>1 holds, are supplied from an initialization control line connected to the display element, and a signal based on the output signal ST_(p+1) from a p′+1′th shift register in the event that q=1 holds, and a signal based on an output signal ST_(p+2) from a p′+2′th shift register in the event that q>1 holds, are supplied from a display control line connected to the display element.

Now, from the perspective of shortening the length of wiring from the initialization control line to a predetermined NAND circuit, with a display element where signals based on scanning signals from the (p′, q)′th NAND circuit are supplied via a scanning line, a configuration is preferable wherein a signal based on a scanning signal from a (p′−1, q′)′th NAND circuit in the event that q=1 holds, and signals based on scanning signals from a (p′, q−1)′th NAND circuit in the event that q>1 holds, are supplied from an initialization control line connected to the display element.

With a configuration wherein a first start pulse and a second start pulse are input to a first stage shift register within a period equivalent to one field period, an arrangement may be made wherein a period identifying signals is a signal which is at a low level or a high level in a period from the start of the first start pulse to the start of the second start pulse, and is at a high level or a low level in a period from the start of the second start pulse to the start of the first start pulse in the next frame. Thus, two periods can be identified using a single period identifying signal. Also, with a configuration wherein a first start pulse through a fourth start pulse are input to a first stage shift register within a period equivalent to one field period, an arrangement may be made wherein the period identifying signal is configured of a first period identifying signal and a second period identifying signal, thereby enabling identifying of four periods with the combination of high/low level of the first period identifying signal and second period identifying signal.

An arrangement may be made wherein, in a period including a period where the portion of the output signal SI_(p′) corresponding to the first start pulse is applied, a signal based on the period identifying signal is applied to the input side of the (p′, q)′th NAND circuit, such that a signal based on the period identifying signal goes to a high level, but otherwise is at a low level. Note that in the event that the period identifying signal is configured of a first period identifying signal and a second period identifying signal, a signal based on the period identifying signal may be applied to the input side of the (p′, q)′th NAND circuit such that a signal based on the first period identifying signal and a signal based on the second period identifying signal both go to a high level only in the period including a period where the portion of the output signal ST_(p′) corresponding to the first start pulse is applied. More specifically, it is sufficient for the period identifying signal to be input to the input side of the NAND circuit, either directly or via a NOR circuit, such that the above-described conditions are satisfied. Accordingly, the operations of the (p′, q)′th NAND circuit are restricted, and the NAND circuit only generates scanning signals based on the portion of the output signal ST_(p) corresponding to the first start pulse, the signal obtained by inverting the output signal ST_(p+1), and the q′th enable signal EN_(q).

With the display device according to an embodiment of the present invention having the scan driving circuit according to an embodiment of the present invention, signals for the scanning lines, initialization control lines, and display control lines, are supplied based on signals from the scan driving circuit. Accordingly, reduction in layout area of the circuits and reduction of circuit costs can be realized. Values of P and Q, and/or the value of U, should be set as appropriate for the specifications and so forth of the scan driving circuit and display device.

Also, with the display device according to an embodiment of the present invention, the display control lines are supplied with signals based on output signals from shift registers making up the scan driving circuit. With the scan driving circuit according to an embodiment of the present invention, a first start pulse through a U′th start pulse are input to the first stage shift register in a period equivalent to one field period. However, scanning signals output from the NAND circuit are not affected by the number of start pulses input to the first stage shift register. Accordingly, multiple pulse signals can be supplied to a display control line within one field period without affecting signals supplied to scanning lines and initialization control lines, by a simple arrangement of changing the number of start pulses input to the first stage shift register.

Note that the scanning signals from the NAND circuit and the output signals from the shift register should be inverted as appropriate and then supplied, depending on the polarity and the like of the transistors making up the display element. The term “a signal based on a scanning signal” may refer to the scanning signal itself, or may refer to a signal where the polarity of the scanning signal has been inverted. In the same way, the term “a signal based on an output signal from the shift register” may refer to the output signal from the shift register itself, or may refer to a signal where the polarity of the output signal from the shift register has been inverted.

The scan driving circuit according to an embodiment of the present invention can be manufactured by widely-employed semiconductor manufacturing techniques. The shift registers making up the shift register unit, the NAND circuits and NOR circuits configuring the logic circuit unit may be configurations and structures which are widely employed. The scan driving circuit may be configured as an independent circuit, or may be configured integrally with the display device. For example, in the event that the display elements configuring the display device have transistors, the scan driving circuit can be manufactured at the same time with the process for manufacturing the display elements.

With the display device according to an embodiment including various preferred configurations, display elements of a configuration so as to be scanned by signals from scanning lines and subjected to an initialization process based on signals from initialization control lines, and further display elements of a configuration wherein display periods and non-display periods are switched by signals from display control lines, can be widely used.

The display elements configuring the display device according to an embodiment of the present invention may include:

(1-1) a driving circuit including a write transistor, a driving transistor, and a capacitance unit; and

(1-2) a light emitting unit to which current is applied via the driving transistor. The light-emitting unit may be configured of a light emitting unit which emits light under application of electric current, examples of which include an organic electroluminescence unit, an inorganic electroluminescence unit, an LED light emitting unit, a semiconductor laser light emitting unit, and so forth. Of these, a configuration of light emitting units which are organic electroluminescence units is preferable from the perspective of configuring a flat display device for color display.

With the driving circuit configuring the display element as described above (hereinafter, may be referred to as “driving circuit configuring the display element according to an embodiment of the present invention”), an arrangement may be made wherein,

with regard to the write transistor,

-   -   (a-1) one source/drain region is connected to the data line, and     -   (a-2) the gate electrode is connected to the scanning line;

and wherein, with regard to the driving transistor,

-   -   (b-1) one source/drain region is connected to the other         source/drain region of the write transistor, thereby configuring         a first node;

and wherein, with regard to the capacitance unit,

-   -   (c-1) a predetermined reference voltage is applied to one end         thereof, and     -   (c-2) the other end is connected with the gate electrode of the         driving transistor, thereby configuring a second node;

and wherein the write transistor is controlled by signals from the scanning line.

The driving circuit configuring the display element according to an embodiment of the present invention may further include

(d) a first switch circuit unit connected between the second node and the other source/drain region of the driving transistor;

wherein the first switch circuit unit is controlled by signals from the scanning line.

The driving circuit configuring the display element including the above-described preferred configuration of an embodiment of the present invention may further include

(e) a second switch circuit unit connected between the second node and a power supply line to which a predetermined initialization voltage is applied;

wherein the second switch circuit unit is controlled by signals from the initialization control line.

The driving circuit configuring the display element including the above-described preferred configuration of an embodiment of the present invention may further include

(f) a third switch circuit unit connected between the first node and a power supply line to which a driving voltage is applied;

wherein the third switch circuit unit is controlled by signals from the display control line.

The driving circuit configuring the display element including the above-described preferred configuration of an embodiment of the present invention may further include

(g) a fourth switch circuit unit connected between the other source/drain region of the driving transistor and one end of the light emitting unit;

wherein the fourth switch circuit unit is controlled by signals from the display control line.

With a display device having a driving circuit including the above-described first switch circuit unit through fourth switch circuit unit, the light emitting unit may be driven by

(a) performing an initialization process of applying a predetermined initial voltage from a power supply line to a second node via the second switch circuit unit in an on state, following which the second switch circuit unit is placed in an off state, thereby setting the potential of the second node to a predetermined reference potential;

(b) performing a writing process of maintaining the off state of the second switch circuit unit, third switch circuit unit, and fourth switch circuit unit, while placing the first switch circuit unit in an on state, and in a state where the second node and the other source/drain region of the driving transistor are electrically connected by the first switch circuit unit in the on state, a video signal is applied to the first node form the data line via the write transistor placed in an on state by a signal from the scanning line, thereby changing the potential of the second node toward a potential which can be calculated by subtracting the threshold voltage of the driving transistor from the video signal;

(c) subsequently placing the write transistor in an off state by a signal from the scanning line; and

(d) and subsequently maintaining the off state of the first switch circuit unit and second switch circuit unit while electrically connecting the other source/drain region of the driving transistor to one end of the light emitting unit via the fourth switch circuit unit in the on state, and applying a predetermined driving voltage to the first node from the power supply line via the third switch circuit unit in the on state, thereby applying current to the light emitting unit via the driving transistor, and thus driving the light emitting unit.

With the driving circuit configuring the display device according to an embodiment of the present invention, a predetermined reference voltage is applied to one end of the capacitance unit, whereby the potential at the one end of the capacitance unit is maintained when the display device is operating. The value of the predetermined reference voltage is not restricted in particular. For example, a configuration may be made wherein one end of the capacitance unit is connected to a power supply line for applying predetermined voltage to the other end of the light emitting unit, so that the predetermined voltage is applied as the reference voltage.

With the display device according to an embodiment of the present invention including the above-described various preferred configurations, the configurations and structures of various wiring such as the scanning lines, initialization control lines, display control lines data lines, power supply lines, and so forth, may be of configurations and structures widely in use. Also, the configuration and structure of the light emitting unit may be of configurations and structures widely in use. Specifically, in the case of forming the light emitting unit as an organic electroluminescence light emitting unit, the light emitting unit may be configured of an anode electrode, hole transporting layer, emissive layer, electron transporting layer, cathode electrode, and so forth. Also, the configuration and structure of the signal output circuit connected to the data line, and so forth, may be of configurations and structures widely in use.

The display device according to an embodiment of the present invention may be of a so-called black-and-white display configuration, or may be of a configuration wherein each pixel is configured of multiple sub-pixels, specifically, a configuration wherein a pixel is confirmed of the three sub pixels of a red light emitting sub-pixel, a green light emitting sub-pixel, and a blue light emitting sub-pixel. Further, a pixel may be configured of a set where one type of multiple types of sub-pixels are added to the above three types of sub pixels (e.g., a set wherein a sub-pixel emitting white light is added for improving luminance, set wherein a sub-pixel emitting a complementary color is added for expanding the range of color reproduction, a set wherein a sub-pixel emitting yellow light is added for expanding the range of color reproduction, a set wherein sub-pixels emitting yellow and cyan light are added for expanding the range of color reproduction).

Examples of image display resolution regarding the number of pixels of the display device include, but are not restricted to, VGA (640, 480), S-VGA (800, 600), XGA (1024, 768), APRC (1152, 900), S-XGA (1280, 1024), U-XGA (1600, 1200), HD-TV (1920, 1080), Q-XGA (2048, 1536) and so forth, and also (1920, 1035), (720, 480), (1280, 960) and so forth. In the case of a black-and-white display device, basically, display elements of the same number as the number of pixels are formed in matrix fashion. In the case of a color display device, basically, display elements threefold the number of pixels are formed in matrix fashion. The display elements may be formed in a striped array, or in a delta array, and should be arrayed as appropriate in accordance with the design of the display device.

With the driving circuit making up the display element according to an embodiment of the present invention, the write transistor and driving transistor may be configured of p-channel type thin-film transistors (TFT), for example. Note that the write transistor may be an n-channel type instead. The first switch circuit unit, second switch circuit unit, third switch circuit unit, and fourth switch circuit unit may be configured of widely-used switching devices such as TFTs, and may be p-channel type TFTs or re-channel type TFTs, for example.

With the driving circuit making up the display element according to an embodiment of the present invention, the capacitance unit making up the driving circuit may be configured of one electrode, another electrode, and a dielectric layer (insulating layer) between these electrodes. The transistors and capacitance unit making up the driving circuit may be formed within a certain plane, and formed on a supporting body, for example. In the event that the light emitting unit is to be an organic electroluminescence light emitting unit, the light emitting unit may be formed above the transistors and capacitance unit making up the driving circuit. Also, the other source/drain region of the driving transistor may be connected to one end of the light emitting unit (anode electrode provided to the light emitting unit, etc.) via another transistor, for example. Also note that a configuration may be employed wherein transistors are formed on a semiconductor substrate.

Note that in the Present Specification, the term “one source/drain region” may be used regarding the one of the two source/drain regions which a transistor has, which is connected to the power source side. Also, the term that a transistor is in an “on state” means that a channel is formed between the source/drain regions, regardless of whether or not current is flowing from one source/drain region to the other source/drain region. Conversely, the term that a transistor is in an “off state” means that no channel is formed between the source/drain regions. The expression that a source/drain region of a certain transistor is connected to a source/drain region of another transistor means that the source/drain region of the certain transistor and the source/drain region of the other transistor occupy the same region. Further, the source/drain regions are not restricted to being configured of impurity-doped polysilicon, amorphous silicon, and the like, and may also be configured of layered strictures thereof, or layers of organic material (electroconductive polymers). Moreover, in the timing charts used for description in the Present Specification, it should be noted that the length of the horizontal axis representing periods (length of time) is a schematic representation, not necessarily indicating the ratio of duration of the time periods.

With the display device according to an embodiment of the present invention having the scan driving circuit according to an embodiment of the present invention, signals for the scanning lines, initialization control lines, and display control lines, are supplied based on signals from the scan driving circuit. Accordingly, reduction in layout area of the circuits and reduction of circuit costs can be realized.

With the scan driving circuit according to an embodiment of the present invention, multiple pulse signals can be supplied to a display control line within one field period without affecting signals supplied to scanning lines and initialization control lines, by a simple arrangement of changing the number of start pulses input to the first stage shift register. Also, with the display device according to an embodiment of the present invention, flickering of the image displayed on the display device can be reduced by a simple arrangement of changing the number of start pulses input to the first stage shift register configuring the scan driving circuit.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a circuit diagram of a scan driving circuit according to a first embodiment;

FIG. 2 is a conceptual diagram of a display device according to the first embodiment, including the scan driving circuit shown in FIG. 1;

FIG. 3 is a schematic timing chart of a shift register unit making up the scan driving circuit shown in FIG. 1;

FIG. 4 is a schematic timing chart of an upstream stage of a logic circuit unit making up the scan driving circuit shown in FIG. 1;

FIG. 5 is a schematic timing chart of a downstream stage of a logic circuit unit making up the scan driving circuit shown in FIG. 1;

FIG. 6 is an equivalent circuit diagram of a driving circuit making up a display element at the m′th row and n′th column of the display device shown in FIG. 2;

FIG. 7 is a partial cross-sectional diagram of a portion of a display element making up the display device shown in FIG. 2;

FIG. 8 is a schematic driving timing chart of a display element at the m′th row and n′th column;

FIGS. 9A and 9B are diagrams schematically illustrating the on/off states of the transistors in the driving circuit making up the display element at the m′th row and n′th column;

FIGS. 10A and 10B are diagrams continuing from FIGS. 9A and 9B, schematically illustrating the on/off states of the transistors in the driving circuit making up the display element at the m′th row and n′th column;

FIGS. 11A and 11B are diagrams continuing from FIGS. 10A and 10B, schematically illustrating the on/off states of the transistors in the driving circuit making up the display element at the m′th row and n′th column;

FIGS. 12A and 12B are diagrams continuing from FIGS. 11A and 11B, schematically illustrating the on/off states of the transistors in the driving circuit making up the display element at the m′th row and n′th column;

FIG. 13 is a circuit diagram of a scan driving circuit according to a comparative example;

FIG. 14 is a timing chart of the scan driving circuit shown in FIG. 13 regarding the leading edges of start pulses between the start and end of a period T₁ and trailing edges of start pulses between the start and end of a period T₅;

FIG. 15 is a timing chart illustrating a case at the scan driving circuit according to the comparative example wherein a first start pulse and a second start pulse have been input to a first stage shift register during a period equivalent to one field period;

FIG. 16 is a circuit diagram of a scan driving circuit according to a second embodiment;

FIG. 17 is a schematic timing chart of a shift register unit making up the scan driving circuit shown in FIG. 16;

FIG. 18 is a schematic timing chart of an upstream stage of a logic circuit unit making up the scan driving circuit shown in FIG. 16;

FIG. 19 is a schematic timing chart of a downstream stage of a logic circuit unit making up the scan driving circuit shown in FIG. 16;

FIG. 20 is a circuit diagram of a driving circuit making up a display element at the m′th row and n′th column;

FIG. 21 is a circuit diagram of a scan driving circuit according to a third embodiment;

FIG. 22 is a schematic timing chart of a shift register unit making up the scan driving circuit shown in FIG. 21;

FIG. 23 is a schematic timing chart of an upstream stage of a logic circuit unit making up the scan driving circuit shown in FIG. 21;

FIG. 24 is a schematic timing chart of a downstream stage of a logic circuit unit making up the scan driving circuit shown in FIG. 21;

FIG. 25 is a circuit diagram of a driving circuit making up a display element at the m′th row and n′th column;

FIG. 26 is an equivalent circuit diagram of a driving circuit making up a display element at the m′th row and n′th column in a display device where display elements are arrayed in two-dimensional matrix fashion;

FIG. 27A is a schematic timing chart of signals on an initialization control line, scanning line, and display control line;

FIG. 27B is a schematic diagram illustrating the on/off states of the transistors of the driving circuit; and

FIGS. 28A and 28B are diagrams continuing from FIG. 27B, schematically illustrating the on/off states of the transistors in the driving circuit.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiments of the present invention will be described with reference to the drawings.

First Embodiment

The first embodiment relates to a scan driving circuit and to a display device having the scan driving circuit. The display device according to the first embodiment is a display device which uses display elements having a light emitting unit and a driving circuit thereof.

FIG. 1 is a circuit diagram of a scan driving circuit 110 according to the first embodiment, FIG. 2 is a conceptual diagram of a display device 1 according to the first embodiment, including the scan driving circuit shown in FIG. 1, FIG. 3 is a schematic timing chart of a shift register unit 111 configuring the scan driving circuit 110 shown in FIG. 1, FIG. 4 is a schematic timing chart of an upstream stage of a logic circuit unit 112 configuring the scan driving circuit 110 shown in FIG. 1, FIG. 5 is a schematic timing chart of a downstream stage of the logic circuit unit 112 making up the scan driving circuit 110 shown in FIG. 1, and FIG. 6 is an equivalent circuit diagram of a driving circuit 11 making up a display element 10 at the m′th (where m=1, 2, 3 . . . M) row and n′th (where n=1, 2, 3 . . . N) column of the display device shown in FIG. 2.

First, the overview of the display device 1 will be described. As shown in FIG. 2, the display device 1 includes:

(1) display elements 10 arrayed in the form of a two-dimensional matrix;

(2) scanning lines SCL, initialization control lines AZ configured to initialize the display elements 10, and display control lines CL configured to control lit/unlit states of the display elements, extending in a first direction;

(3) data lines DTL extending in a second direction different from the first direction; and

(4) a scan driving circuit 110. The scanning lines SCL, initialization control lines AZ, and display control lines CL are connected to the scan driving circuit 110. The data lines DTL are connected to a signal output circuit 100. Note that in FIG. 2, 3×3 display elements 10 are shown centered on a display element 10 at the m′th row and n′th column, but this is only an exemplary illustration. Also, the power supply lines PS₁, PS₂, and PS₃, shown in FIG. 6, have been omitted from FIG. 2.

N display elements 10 are arrayed in the first direction and M are arrayed in the second direction which is different from the first direction. The display device 1 is configured of N/3×M pixels arrayed on a two-dimensional matrix form. One pixel is configured of three sub-pixels (a red light emitting sub-pixel which emits red light, a green light emitting sub-pixel which emits green light, and a blue light emitting sub-pixel which emits blue light). The display elements 10 making up the pixels are driven in line sequence, at a display frame rate of FR (times/second). That is to say, the display elements 10 making up of each of the N/3 pixels arrayed at the m′th row (N sub-pixels) are driven at the same time. In other words, the lit/unlit timing of the display elements 10 making up one row are subjected to control in increments of the row to which they belong.

As shown in FIG. 6, a display element 10 is configured of a driving circuit 11 having a write transistor TR_(W), driving transistor TR_(D), and capacitance unit C₁, and a light emitting unit ELP to which current is applied via the driving transistor TR_(D). The light emitting unit ELP is configured of an electroluminescence light emitting unit. The display element 10 has a structure wherein the driving circuit 11 and the light emitting unit ELP are layered. The driving circuit 11 further has a first transistor TR₁, second transistor TR₂, third transistor TR₃, and fourth transistor TR₄; these transistors will be described later.

With the display element 10 at the m′th row and n′th column, one source/drain region of the write transistor TR_(W) us connected to the data line DTL_(n), and the gate electrode is connected to the scanning line SCL_(m). At the driving transistor TR_(D), one source/drain region is connected to the other source/drain region of the write transistor TR_(W), thereby configuring a first node ND₁. One end of the capacitance unit C₁ is connected to the power supply line PS₁. At the capacitance unit C₁, a predetermined reference voltage (a later-described predetermined driving voltage V_(CC) in the first embodiment) is applied to one end thereof, and the other end thereof is connected to the gate electrode of the driving transistor TR_(D), thereby configuring a second node ND₂. The write transistor TR_(W) is controlled by signals from the scanning line SCL_(m).

Video signals (driving signals, luminance signals) V_(Sig) are applied to the data line DTL_(n) from the signal output circuit 100 to control luminance a the light emitting unit ELP, a point which will be described later.

The driving circuit 11 further has a first switch circuit unit SW₁ connected between the second node ND₂ and the other source/drain region of the driving transistor TR_(D). The first switch circuit unit SW₁ is configured of the first transistor TR₁. At the first transistor TR₁, one source/drain region is connected to the second node ND₂, and the other source/drain region is connected to the other source/drain region of the driving transistor TR₁. The gate electrode of the first transistor TR₁ is connected to the scanning line SCL_(m), and the first transistor TR₁ is controlled by signals from the scanning line SCL_(m).

The driving circuit 11 further has a second switch circuit unit SW₂ connected between the second node ND₂ and the power supply line PS₃ to which the later-described predetermined initialization voltage V_(Ini) is applied. The second switch circuit unit SW₂ is configured of the second transistor TR₂. At the second transistor TR₂, one source/drain region is connected to the power supply line PS₃, and the other source/drain region is connected to the second node ND₂. The gate electrode of the second transistor TR₂ is connected to the initialization control line AZ_(m), and the second transistor TR₂ is controlled by signals from the initialization control line AZ_(m).

The driving circuit 11 further has a third switch circuit unit SW₃ connected between the first node ND_(D) and the power supply line PS_(D) to which the driving voltage V_(CC) is applied. The third switch circuit unit SW₃ is configured of the third transistor TR₃. At the third transistor TR₃, one source/drain region is connected to the power supply line PS_(D), and the other source/drain region is connected to the first node ND₁. The gate electrode of the third transistor TR₃ is connected to the display control line CL_(m), and the third transistor TR₃ is controlled by signals from the display control line CL_(m).

The driving circuit 11 further has a fourth switch circuit unit SW₄ connected between the other source/drain region of the driving transistor TR_(D) and one end of the light emitting unit ELP. The fourth switch circuit unit SW₄ is configured of the fourth transistor TR₄. At the fourth transistor TR₄, one source/drain region is connected to other source/drain region of the driving transistor TR_(D), and the other source/drain region is connected to one end of the light emitting unit ELP. The gate electrode of the fourth transistor TR₄ is connected to the display control line CL_(m), and the fourth transistor TR₄ is controlled by signals from the display control line CL_(m). The other end of the light emitting unit ELP (cathode electrode) is connected to the power supply line PS₂, whereby a later-described voltage V_(cat) is applied. The symbol C_(EL) represents the capacitance of the light emitting unit ELP.

The driving transistor TR_(D) is configured of a p-channel type TFT, and the write transistor TR_(W) also is configured of a p-channel type TFT. Further, the first transistor TR₁, second transistor TR₂, third transistor TR₃, and fourth transistor TR₄ are also configured of a p-channel type TFTs. Note that the write transistor TR_(W) may be configured of an n-channel type TFT instead. The transistors are described as being depression type transistors, but are not restricted to this.

Widely-used configurations and structures may be used for the configurations and structures of the signal output circuit 100, scanning lines SCL, initialization control lines AZ, display control lines CL, and data lines DTL. The power supply lines PS₁, PS₂, and PS₃ extending in the same first direction as the scanning lines SCL are connected to an unshown power source unit. The driving voltage V_(CC) is applied to the power supply line PS₁, the voltage V_(cat) is applied to the power supply line PS₂, and the initialization voltage V_(Ini) is applied to the power supply line PS₃. Widely-used configurations and structures may be used for the configurations and structures of the power supply lines PS₁, PS₂, and PS₃ as well.

FIG. 7 is a partial cross-sectional diagram of a portion of a display element 10 making up the display device 1 shown in FIG. 2. Each transistor and the capacitance unit C₁ making up the driving circuit 11 of the display element 10 are formed on a supporting body 20, and the light emitting unit ELP is formed above the transistors and the capacitance unit C₁ making up the driving circuit 11, with an inter-layer insulating layer 40 introduced therebetween, an arrangement which will be described later. The light emitting unit ELP has a widely-used configuration and structure of an anode electrode, hole transporting layer, emissive layer, electron transporting layer, cathode electrode, and so forth, for example. Note that in FIG. 7, only the driving transistor TR_(D) is shown, and other transistors are hidden and are not visible. The other source/drain region of the driving transistor TR_(D) is electrically connected to an anode electrode provided to the light emitting unit ELP via the unshown fourth transistor TR₄, the connection between the fourth transistor TR₄ and the anode electrode of the light emitting unit ELP also not being visible.

The driving transistor TR_(D) is configured of a gate electrode 31, gate insulating layer 32, and semiconductor layer 33. More specifically, the driving transistor TR_(D) has a channel formation region 34 corresponding to the semiconductor layer 33 between the one source/drain region 35 and the other source/drain region 36 provided to the semiconductor layer 33. The other unshown transistors are also of similar configuration.

The capacitance unit C₁ is configured of an electrode 37, a dielectric layer configured of an extended portion of the gate insulating layer 32, and an electrode 38. Note that the connection between the electrode 37 and the gate electrode 31 of the driving transistor TR_(D), and the connection between the electrode 38 and the power supply line PS₁, are not visible.

The gate electrode 31, part of the gate insulating layer 32, and the electrode 37 making up the capacitance unit C₁, are formed on the supporting body 20. The driving transistor TR_(D) and capacitance unit C₁ and so forth are covered with the inter-layer insulating layer 40, with the light emitting unit ELP configured of an anode electrode 51, hole transporting layer, emissive layer, electron transporting layer, and cathode electrode 53 provided upon the inter-layer insulating layer 40. Note that in FIG. 7, the hole transporting layer, emissive layer, and electron transporting layer are represented with a single layer 52. A second inter-layer insulating layer 54 is provided on the inter-layer insulating layer 40 where the light emitting unit ELP is not provided, a transparent substrate 21 us disposed above the second inter-layer insulating layer 54 and cathode electrode 53, and the light emitted at the emissive layer is externally emitted through the substrate 21. Wiring 39 making up the cathode electrode 53 and power supply line PS₂ is connected thereto via contact holes 56 and 55 provided in the second inter-layer insulating layer 54 and inter-layer insulating layer 40, respectively.

A manufacturing method of the display device shown in FIG. 7 will be described. First, the various types of wiring for the scanning lines and so forth, electrodes making up the capacitance units, transistors formed of semiconductor layers, inter-layer insulating layers, contact holes, and so forth, are formed on the supporting body 20 by techniques which are widely employed. Next, film formation and patterning is performed by techniques which are widely employed, thereby forming light emitting units ELP arrayed in matrix fashion. The supporting body 20 which has been subjected to the above processes is made to face a substrate 21 and the perimeter thereof is sealed. This is then connected with the signal output circuit 100 and scan driving circuit 110, whereby a display device can be completed.

Next, the scan driving circuit 110 will be described. Note that description of the scan driving circuit 110 will be made with reference to an arrangement wherein scanning signals for supply to scanning line SCL₁ through scanning line SCL₃₁ in line sequence, to facilitate description. Description will be made in this way in other embodiments as well.

As shown in FIG. 1, the scan driving circuit 110 includes:

(A) a shift register unit 111 configured of P (wherein P is a natural number of 3 or greater, hereinafter the same) stages of shift registers SR, to sequentially shift input start pulses STP and output output signals ST from each stage; and

(B) a logic circuit unit 112 configured to operate based on output signals ST from the shift register unit 111, and enable signals (with the first embodiment, later-described first enable signal EN₁ and second enable signal EN₂).

With the output signals of a p′th (where p=1, 2, . . . P−1) stage shift register SR_(p) represented as ST_(p), the start of a start pulse of an output signal ST_(p+1) of a p+1′th shift register SR_(p+1) is situated between the start and end of a start pulse of the output signal ST_(p), as shown in FIG. 3. The shift register unit 111 operates based on clock signals CK and start pulses STP, so as to satisfy the above conditions.

The first stage shift register SR₁ receives input of a first start pulse through a U′th start pulse (wherein U is a natural number of 2 or greater, hereinafter the same) within a period equivalent to one field period (in FIG. 3, a period equivalent from the start of period T₁ through the end of period T₃₂. Note that in the first embodiment, U=2, and a first start pulse and a second start pulse are input.

Specifically, the first start pulse input to the first stage shift register SR₁ has the leading edge thereof between the start and end of the period T₁ shown in FIG. 3, and has the trailing edge thereof between the start and end of the period T₁₃. Also, the second start pulse has the leading edge thereof between the start and end of the period T₁₇ shown in FIG. 3 and has the trailing edge thereof between the start and end of the period T₂₉. Each period such as T₁ in FIG. 3 and other later-described drawings correspond to one horizontal scanning period (also represented by “1H”). The clock signal CK is a square wave signal which inverts polarity every two horizontal scanning periods (2H).

The first start pulse in the output signal ST₁ of the shift register SR₁ has the leading edge thereof at the start of the period T₃, and has the trailing edge at the end of period T₁₄. The first pulse in the output signals ST₂, ST₃, and so on, for the shift register SR₂ and subsequent shift registers is a pulse which has been sequentially shifted by two horizontal scanning periods. Also, second start pulse in the output signal ST₁ of the shift register SR₁ has the leading edge thereof at the start of the period T₁₉, and has the trailing edge at the end of period T₃₀. The first pulse in the output signals ST₂, ST₃, and so on, for the shift register SR₂ and subsequent shift registers is also a pulse which has been sequentially shifted by two horizontal scanning periods.

Also, one each of a first enable signal through a Q′th enable signal (where Q is a natural number of 2 or greater, hereinafter the same) exist in sequence between the start of the first start pulse of the output signal ST_(p) and the start of the first start pulse of the output signal ST_(p+1). In the first embodiment Q=2, and there are one each of the first enable signal EN₁ and the second enable signal EN₂, in sequence. In other words, the first enable signal EN₁ and the second enable signal EN₂ are signals generated so as to satisfy the above conditions, which basically are square wave signals of the same cycle but with different phases. Note that one each of a first enable signal through a Q′th enable signal also exist in sequence between the start of the second start pulse of the output signal ST_(p) and the start of the second start pulse of the output signal ST_(p+1).

Specifically, the first enable signal EN₁ and the second enable signal EN₂ are square wave signals having two horizontal scanning periods as one cycle. In the first embodiment, these signals invert polarity every horizontal scanning period, and the first enable signal EN₁ and the second enable signal EN₂ are in inverse phase relation. While FIGS. 3 through 5 show the high level of the enable signals EN₁ and EN₂ as lasting for one horizontal scanning period, the present invention is not restricted to this arrangement, and the high level may be a square wave signal with a period shorter than one horizontal scanning period, a point which holds true with the other embodiments as well.

For example, there sequentially exist one each of the first enable signal EN₁ in the period T₃ and the second enable signal EN₂ in the period T₄, between the start of the start pulse in output signal ST₁ (i.e., the start of period T₃) and the start of the start pulse in output signal ST₂ (i.e., the start of period T₃). In the same way, there sequentially exist one each of the first enable signal EN₁ and the second enable signal EN₂, between the start of the start pulse in output signal ST₂ and the start of the start pulse in output signal ST₃. This is the same for output signal ST₄ and on.

As shown in FIG. 1, the logic circuit unit 112 has (P−2)×Q NAND circuits 113. Specifically, the logic circuit unit 112 has (1, 1)′th through (P−2, 2)′th NAND circuits 113. Period identifying signals SP for identifying each period from the start of the u′th start pulse (where u=1, 2, . . . U−1, hereinafter the same) start pulse in an output signal ST₁ to the start of a (u+1)′th start pulse, and a period from the start of the U′th start pulse to the start of the first start pulse in the next frame, are input to the logic circuit unit 112.

In the first embodiment, U=2, and the period identifying signal SP is a signal for identifying the period from the start of the first start pulse in the output signal ST₁ to the start of the second start pulse, and the period from the start of the second start pulse in output signal ST₁ to the start of the first start pulse in the next frame. In FIGS. 3 through 5, the period from the start of the first start pulse in the output signal ST₁ to the start of the second start pulse is a period from the start of period T₃ to the end of period T₁₈. Also, the period from the start of the second start pulse in output signal ST₁ to the start of the first start pulse in the next frame is a period from the start of period T₁₉ to the end of period T₂ in the next frame. In the first embodiment, the period identifying signal SP is a signal which is at high level during the period from the start of period T₃ to the end of period T₁₈, and at low level during the period from the start of period T₁₉ to the end of period T₂ of the next frame.

With a q′th enable signal (where q is an arbitrary number from 1 to Q, hereinafter the same) represented as EN_(q), a signal based on the period identifying signal SP, the output signal ST_(p), a signal obtained by inverting the output signal ST_(p+1), and the q′th enable signal EN_(q), are input to a (p′, q)′th NAND circuit 113 (where p is an arbitrary natural number from 1 to (P−2), hereinafter the same). As described later, the operations of the NAND circuit 113 are restricted based on the period identifying signal SP, such that the NAND circuit 113 generates scanning signals based only on a portion of the output signal ST_(p)′ corresponding to the first start pulse, the signal obtained by inverting the output signal ST_(p′+1) and the q′th enable signal EN_(q).

More specifically, the output signal ST_(p′+1) is inverted by the NOR circuit 114 shown in FIG. 1, and input to the input side of the (p′, q)′th NAND circuit 113. The output signal ST_(p′) and the q′th enable signal EN_(q) are directly input to the input side of the (p′, q)′th NAND circuit 113. Also, the period identifying signal SP is directly input to the input side of the (1, 1)′th through (8, 2)′th NAND circuits 113, as a signal based on the period identifying signal SP. the period identifying signal SP inverted by a NOR circuit 116 shown in FIG. 1 is input to the input side of the (9, 1)′th and subsequent NAND circuits 113, as a signal based on the period identifying signal SP.

As described above, the first start pulse and second start pulse are input to the first stage shift register SR₁ within a period equivalent to one field period. If the (p′, q)′th NAND circuit 113 were to operate only by the output signal ST_(p′), a signal obtained by inverting the output signal ST_(p′+1), and the q′th enable signal EN_(q), the NAND circuit 113 would generate two scanning signals in the one field period. This will be described in detail next.

Let us consider the (8, 1)′th NAND circuit 113. Signals based on the scanning signals from the (8, 1)′th NAND circuit 113 are supplied to the scanning line SCL₁₄. As shown in FIG. 4, in the period T₁₇ in which the scanning signal should be generated, the output signal ST₈, the signal obtained by inverting the output signal ST₉, and the first enable signal EN₁, are at high level. However, the first stage shift register SR₁ has also received input of the second start pulse in addition to the first start pulse, so the output signal ST₈, the signal obtained by inverting the output signal ST₉, and the first enable signal EN₁, are at high level in period T₁ as well.

Accordingly, if the (8, 1)′th NAND circuit 113 were to operate based only on the output signal ST₈, a signal obtained by inverting the output signal ST₉, and the first enable signal EN₁, trouble would occur in that a scanning signal would be supplied to the scanning line SCL₁₄ not only in the period T₁₇ in which the scanning signal should be generated, but also in the period T₁.

In the first embodiment, the operations of the NAND circuit 113 are restricted based on the period identifying signal SP, so trouble where a scanning signal is supplied in the period T₁ does not occur. That is to say, the period identifying signal SP is directly input to the input side of the (8, 1)′th NAND circuit 113, as a signal based on the period identifying signal SP, as described above. In period T₁, the period identifying signal SP is at a low level. Accordingly, in period T₁ the operations of the NAND circuit 113 are restricted, and do not generate a scanning signal. On the other hand, in period T₁₇, the period identifying signal SP is at a high level. Accordingly, the (8, 1)′th NAND circuit 113 generates a scanning signal based only on a portion of the output signal ST₈ corresponding to the first start pulse, a signal obtained by inverting the output signal ST₉, and the first enable signal EN₁.

Let us also consider the (9, 1)′th NAND circuit 113. Signals based on the scanning signals from the (9, 1)′th NAND circuit 113 are supplied to the scanning line SCL₁₆ shown in FIG. 1. A signal based on the period identifying signal SP, the output signal ST₉, the signal obtained by inverting the output signal ST₁₀, and the first enable signal EN₁, are applied to the input side of the (9, 1)′th NAND circuit 113. Unlike the case of the (8, 1)′th NAND circuit 113, a period identifying signal SP inverted by the NOR circuit 116 is input to the input side of the (9, 1)′th NAND circuit 113 as a signal based on the period identifying signal SP.

As shown in FIG. 5, in the period T₁₉ in which the scanning signal should be generated, the output signal ST₉, the signal obtained by inverting the output signal ST₁₉, and the first enable signal EN₁, are at high level. However, the first stage shift register SR₁ has also received input of the second start pulse in addition to the first start pulse, so the output signal ST₉, the signal obtained by inverting the output signal ST₁₉, and the first enable signal EN₁, are at high level in period T₃ as well. As described above, a period identifying signal SP inverted by the NOR circuit 116 is input to the input side of the (9, 1)′th NAND circuit 113. In period T₃, the period identifying signal SP is at a high level, so in period T₃ the (9, 1)′th NAND circuit 113 does not generate a scanning signal. On the other hand, in period T₁₉, the period identifying signal SP is at a low level, so the (9, 1)′th NAND circuit 113 generates a scanning signal in period T₁₉.

While description has been made regarding the operations of the (8, 1)′th NAND circuit 113 and the (9, 1)′th NAND circuit 113, the operations are the same for the other NAND circuits 113 as well. The (p′, q)′th NAND circuit 113 generates a scanning signal based only on a portion of the output signal ST_(p′) corresponding to the first start pulse, the signal obtained by inverting the output signal ST_(p′+1), and the q′th enable signal EN_(q).

Description of the display device 1 will continue. As shown in FIG. 1, signals of the (1, 2)′th NAND circuit 113 are supplied to the scanning line SCL₁ connected to the first row of display elements 10, and signals of the (2, 1)′th NAND circuit 113 are supplied to the scanning line SCL₂ connected to the second row of display elements 10. This is true for the other scanning line SCL as well. That is to say, signals of the (p′, q)′th NAND circuit 113 (excluding a case wherein p′=1 and q=1) are supplied to the scanning line SCL_(m) connected to the m′th (where m=Q×(p′−1)+q−1) row of display elements 10.

The display elements 10 to which signals based on the scanning signals from the (p′, q)′th NAND circuit 113 are supplied via the scanning line SCL_(m) are supplied with signals based on scanning signals from the (p′−1, q′)′th NAND circuit 113 (where q″ is a natural number from 1 through Q, hereinafter the same) in the event that q=1, and signals based on scanning signals from the (p′, q″)′th NAND circuit 113 (where q″ is a natural number from 1 through (q−1), hereinafter the same) in the event that q>1, via the initialization control line AZ, connected to the display elements 10.

More specifically, in the first embodiment, the display elements 10 to which signals based on the scanning signals from the (p′, q)′th NAND circuit 113 are supplied via the scanning line SCL_(m), are supplied with signals based on scanning signals from the (p′−1, Q)′th NAND circuit 113 in the event that q=1, and signals based on scanning signals from the (p′, q−1)′th NAND circuit 113 in the event that q>1, via the initialization control line AZ_(m) connected to the display elements 10.

Also, the display control line CL_(m) connected to the display elements 10 is supplied with signals based on the output signal ST_(p′+1) from the (p′+1)′th stage shift register SR_(p′+1) in the case that q=1, and is supplied with signals based on the output signal ST_(p′+2) from the (p′+2)′th stage shift register SR_(p′+2) in the case that q>1. Note that the third transistor TR₃ and fourth transistor TR₄ shown in FIG. 6 are p-channel type transistors, so signals are supplied to the display control line CL_(m) via the NOR circuit 115.

Description will be made in further detail with reference to FIG. 1. For example, looking at the display elements 10 to which signals based on the scanning signals from the (8′, 1)′th NAND circuit 113 are supplied via the scanning line SCL₁₄, the initialization control line AZ₁₄ connected to the display element 10 is supplied with signals based on the scanning signals from the (7′, 2)′th NAND circuit 113. Signals based on the output signal ST₉ from the ninth stage shift register SR₉ are supplied to the display control line CL₁₄ connected to the display element 10. Also, looking at the display elements 10 to which signals based on the scanning signals from the (8′, 2)′th NAND circuit 113 are supplied via the scanning line SCL₁₅, the initialization control line AZ₁₅ connected to the display element 10 is supplied with signals based on the scanning signals from the (8′, 1)′th NAND circuit 113. Signals based on the output signal ST₁₀ from the tenth stage shift register SR₁₀ are supplied to the display control line CL₁₅ connected to the display element 10.

Next, operation of the display device 1 will be described regarding operations of a display element 10 at the m′th row and n′th column, to which signals of the (p′, q)′th NAND circuit 113 are supplied from the scanning line SCL_(m). This display element 10 will hereinafter be referred to as “(n, m)′th display element 10” or “(n, m)′th sub-pixel”. Also, the horizontal scanning period of the display elements 10 arrayed on the m′th row (more specifically, the m′th horizontal scanning period of the current display frame) will be referred to simply as “m′th horizontal scanning period”. This will be the same for the other embodiments described later, as well.

FIG. 8 is a schematic driving timing chart of the display element 10 at the m′th row and n′th column. Also, FIGS. 9A and 9B are diagrams schematically illustrating the on/off states of the transistors in the driving circuit 11 making up the display element 10 at the m′th row and n′th column. FIGS. 10A and 10B are diagrams continuing from FIGS. 9A and 9B, schematically illustrating the on/off states of the transistors in the driving circuit 11 making up the display element 10 at the m′th row and n′th column. FIGS. 11A and 11B are diagrams continuing from FIGS. 10A and 10B, schematically illustrating the on/off states of the transistors in the driving circuit 11 making up the display element 10 at the m′th row and n′th column. FIGS. 12A and 12B are diagrams continuing from FIGS. 11A and 11B, schematically illustrating the on/off states of the transistors in the driving circuit 11 making up the display element 10 at the m′th row and n′th column.

Note that, for the sake of facilitating description, p′=8 and q=1, and m=14, when comparing the timing chart in FIG. 8 with FIGS. 3 through 5. Specifically, the timing chart of initialization control line AZ₁₄, scanning line SCL₁₄, and display control line CL₁₄ in FIG. 4 is to be referred to.

In the lit state of the display element 10, the driving transistor TR_(D) is driven so as to apply drain current I_(ds) in accordance with the following Expression (1). In the lit state of the display element 10, the one source/drain region of the driving transistor TR_(D) acts as a source region, and the other source/drain region acts as a drain region. To facilitate description, in the following description, the one source/drain region of the driving transistor TR_(D) may be referred to simply as “source region”, and the other source/drain region simply as “drain region”. We will also say that

μ effective mobility, L channel length, W channel width, V_(gs) voltage difference between the source region and gate region, and C_(OX) (relative permittivity of gate insulation layer)×(permittivity of vacuum)/(thickness of gate insulation layer).

I _(ds) =k·μ·(V _(gs) −V _(th))²  (1)

Also, while the following voltage and potential values will be used in the first embodiment and later-described other embodiments, these are only values for explanatory purposes, and the present invention is not restricted to these values. V_(Sig) Video signal for controlling the luminance at the light emitting unit ELP

0 volts (maximum luminance) to 8 volts (minimum luminance)

V_(CC) Driving voltage

10 volts

V_(Ini) Initialization voltage for initializing the potential of the second node ND₂

−4 volts

V_(th) Threshold voltage of driving transistor TR_(D)

2 volts

V_(cat) Voltage applied to power supply line PS₂

−10 volts

Period TP(1)⁻² (See FIGS. 8A through 9A)

The Period TP(1)⁻² is a period in which the (n, m)′th display element 10 is in a lit state, in accordance with the video signal V′_(Sig) written thereto earlier. For example, in the case of m=14, the Period TP(1)⁻² corresponds to the period from the start of the period T′₃ (period corresponding to period T₃ shown in FIG. 4 in the preceding frame) to the end of the period T₁₄. The initialization control line AZ₁₄ and scanning line SCL₁₄ are at the high level, and the display control line CL₁₄ is at the low level.

Accordingly, the write transistor TR_(W), first transistor TR₁, and second transistor TR₂ are in an off state. The third transistor TR₃ and fourth transistor TR₄ are in an on state. The light emitting unit ELP at the display element 10 making up the (n, m)′th display element 10 has applied thereto a drain current I′_(ds) based on a later-described Expression (5), and the luminance of the display element 10 configuring the (n, m)′th sub-pixels is a value corresponding to this drain current I′_(ds).

Period TP(1)⁻¹ (See FIGS. 8A, 8B, and 9B)

The (n, m)′th display element 10 is in an unlit state from this Period TP(1)⁻¹ is to a later-described Period TP(1)₂. For example, in the case of m=14, the Period TP(1)⁻¹ corresponds to the period T′₁₅ in FIG. 4. The initialization control line AZ₁₄ and scanning line SCL₁₄ maintain the high level, and the display control line CL₁₄ goes to the high level.

Accordingly, the write transistor TR_(W), first transistor TR₁, and second transistor TR₂ maintain the off state. The third transistor TR₃ and fourth transistor TR₄ go from the on state to the off state. Thus, the first node ND₁ is in a state of being cut off from the power supply line PS₁, and further, the light emitting unit ELP and driving transistor TR_(D) are in a state of being cut off. Accordingly, current does not flow to the light emitting unit ELP, which is accordingly in an off state.

Period TP(1)₀ (See FIGS. 8A, 8B, and 10A)

The Period TP(1)₀ is the (m−1)′th horizontal scanning period in the current display frame. For example, in the case of m=14, the Period TP(1)₀ corresponds to the period T₁₆ in FIG. 4. The scanning line SCL₁₄ and the display control line CL₁₄ maintain the high level. The initialization control line AZ₁₄ goes to the low level, and then goes to the high level at the end of the period T₁₆.

In this Period TP(1)₀, the first switch circuit unit SW₁, third switch circuit unit SW₃, and fourth switch circuit unit SW₄ maintain the off state, and following applying the predetermined initialization voltage V_(Ini) from the power supply line PS₃ to the second node ND₂ via the second switch circuit unit SW₂ placed in the on state, the second switch circuit unit SW₂ is set to an off state, thereby performing an initialization process for setting the potential of the second node ND₂ to the predetermined reference potential.

That is to say, the write transistor TR_(W), first transistor TR₁, third transistor TR₃, and fourth transistor TR₄ are in an off state. The second transistor TR₂ goes from an off state to an on state, and the predetermined initialization voltage V_(Ini) is applied from the power supply line PS₃ via the second transistor TR₂ placed in the on state. At the end of the Period TP(1)₀, the second transistor TR₂ goes to the off state. The driving voltage V_(CC) is applied to one end of the capacitance unit C₁ such that the potential at the one end of the capacitance unit C₁ is in a maintained state, so the potential of the second node ND₂ is set to the predetermined reference voltage (−4 volts) by the initialization voltage V_(Ini).

Period TP(1)₁ (See FIGS. 8A, 8B, and 10B)

The Period TP(1)₁ is the m′th horizontal scanning period in the current display frame. For example, in the case of m=14, the Period TP(1)₁ corresponds to the period T₁₇ in FIG. 4. The initialization control line AZ₁₄ and the display control line CL₁₄ are at the high level, and the scanning line SCL₁₄ goes to the low level.

In this Period TP(1)₁, the second switch circuit unit SW₂, third switch circuit unit SW₃, and fourth switch circuit unit SW₄ maintain the off state, the first switch circuit unit SW₁ is placed in an on state, and in a state wherein the second node ND₂ and the other source/drain region of the driving transistor TR_(D) are electrically connected by the first switch circuit unit SW₁ in the on state, the video signal V_(Sig) is applied from the data line DTL_(n) to the first node ND₁ via the write transistor TR_(W) placed in the on state by the signals from the scanning line SCL_(m), thereby performing a writing process for changing the potential of the second node ND₂ toward a potential which can be calculated by subtracting the threshold voltage V_(th) of the driving transistor TR_(D) from the video signal V_(Sig).

That is to say, the off state of the second transistor TR₂, third transistor TR₃, and fourth transistor TR₄ is maintained. The write transistor TR_(W) and first transistor TR₁ are placed in an one state by signals from the scanning line SCL_(m). The second node ND₂ and the other source/drain region of the driving transistor TR_(D) are placed in an electrically connected state via the first transistor TR₁ in the on state. Also, the video signal V_(Sig) is applied from the data line DTL_(n) to the first node ND₁ via the write transistor TR_(W) which has been placed in the on state by the signal from the scanning line SCL_(m). Accordingly, the potential of the second node ND₂ changes toward a potential which can be calculated by subtracting the threshold voltage V_(th) of the driving transistor TR_(D) from the video signal V_(Sig).

That is to say, due to the above-described initialization process, the potential of the second node ND₂ is initialized such that the driving transistor TR_(D) is in an on state at the start of the Period TP(1)₁, so the potential of the second node ND₂ changes toward the potential of the video signal V_(Sig) applied to the first node ND₁. However, upon the potential difference between the gate electrode of the driving transistor TR_(D) and the one source/drain region reaching the threshold voltage V_(th), the driving transistor TR_(D) goes to an off state. In this state, the potential of the second node ND₂ is approximately (V_(Sig)−V_(th)). The voltage V_(ND2) of the second node ND₂ is as expressed in the following Expression (2). Before the (m+1)′th horizontal scanning period starts, the write transistor TR_(W) and first transistor TR₁ are placed in an off state by signals from the scanning line SCL_(m).

V _(ND2)≈(V _(Sig) −V _(th))  (2)

Period TP(1)₂ (See FIGS. 8A, 8B, 11A)

The Period TP(1)₂ is a period up to the emitting period starting following the writing process, and the (n, m)′th display element 10 is in an unlit state. For example, in the case of m=14, the Period TP(1)₂ corresponds to the period T₁₈ in FIG. 4. The scanning line SCL₁₄ goes to the high level, and the initialization control line AZ₁₄ and display control line CL₁₄ maintain the high level.

Accordingly, the write transistor TR_(W) and first transistor TR₁ go to an off state, and the second transistor TR₂, third transistor TR₃, and fourth transistor TR₄ maintain the off state. The first node ND₁ maintains the state of being cut off from the power supply line PS₁, and the light emitting unit ELP and driving transistor TR_(D) maintain the state of being cut off. The potential V_(ND2) of the second node ND₂ maintains the above Expression (2) due to the capacitance unit C₁.

Period TP(1)₃ (See FIGS. 8A, 8B, 11B)

In this Period TP(1)₃, the first switch circuit unit SW₁ and second switch circuit unit SW₂ maintain the off state, the other source/drain region of the driving transistor TR_(D) and the one end of the light emitting unit ELP are electrically connected via the fourth switch circuit unit SW₄ placed in an on state, the predetermined driving voltage V_(CC) is applied to the first node ND₁ from the power supply line PS₁ via the third switch circuit unit SW₃ placed on the on state, thereby performing an emitting process for driving the light emitting unit ELP by applying current to the light emitting unit ELP via the driving transistor TR_(D).

For example, in the case of m=14, the Period TP(1)₃ corresponds to the period from the start of period T₁₉ to the end of period T₃₀ in FIG. 4. The initialization control line AZ₁₄ and scanning line SCL₁₄ maintain the high level and the display control line CL₁₄ goes to the low level.

That is to say, the first transistor TR₁ and second transistor TR₂ maintain the off state, and the third transistor TR₃ and fourth transistor TR₄ go from the off state to the on state due to signals from the display control line CL_(m). The predetermined driving voltage V_(CC) is applied to the first node ND₁ via the third transistor TR₃ placed in the on state. Also, the other source/drain region of the driving transistor TR_(D) and the one end of the light emitting unit ELP are electrically connected via the fourth transistor TR₄ which has been placed in the on state. Thus, the light emitting unit ELP is driven by current being applied to the light emitting unit ELP via the driving transistor TR_(D).

Based on Expression (2),

V _(gs) ≈V _(CC)−(V _(Sig) −V _(th))

holds, so Expression (1) can be rewritten as follows.

$\begin{matrix} \begin{matrix} {I_{ds} = {k \cdot \mu \cdot \left( {V_{gs} - V_{th}} \right)^{2}}} \\ {= {k \cdot \mu \cdot \left( {V_{CC} - V_{Sig}} \right)^{2}}} \end{matrix} & (4) \end{matrix}$

Accordingly, the current I_(ds) of the light emitting unit ELP is proportionate to the value of the potential difference between V_(CC) and V_(Sig) squared. In other words, the current I_(ds) flowing through the light emitting unit ELP is not dependent on the threshold voltage V_(th) of the driving transistor TR_(D), meaning that the amount of emission (luminance) of the light emitting unit ELP is not affected by the threshold voltage V_(th) of the driving transistor TR_(D). The luminance of the (n, m)′th display element 10 is a value corresponding to this I_(ds).

Period TP(1)₄ (See FIGS. 8A, 8B, 12A)

In the case of m=14 for example, this Period TP(1)₄ is the period between the end of the second start pulse in the output signal ST₉ (the end of the period T₃₀ in FIG. 4) and immediately before the leading edge of the first start pulse in the next frame (the end of the period T₂ in the next frame in FIG. 4). At the start of this period, the output signal ST₉ goes from the high level to the low level. The display control line CL₈ goes from the low level to the high level. The initialization control line AZ₈ and scanning line SCL₉ maintain the high level.

Accordingly, the third transistor TR₃ and fourth transistor TR₄ go from the on state to the off state. The write transistor TR_(W), first transistor TR₁, and second transistor TR₂ maintain the off state. Accordingly, the first node ND₁ is cut off from the power supply line PS₁, and further, the light emitting unit ELP and driving transistor TR_(D) are in a cut off state. Thus, no current flows to the light emitting unit ELP, which is accordingly in an unlit state.

Period TP(1)₅ (See FIGS. 8A, 8B, 12B)

In the case of m=14 for example, this Period TP(1)₅ is the period after the start of the first start pulse in the next frame (the start of the period T₃ in the next frame in FIG. 4). In this period, the output signal ST₉ goes from the low level to the high level. The display control line CL₈ goes from the high level to the low level. The initialization control line AZ₈ and scanning line SCL₈ maintain the high level.

Accordingly, the third transistor TR₃ and fourth transistor TR₄ go from the off state to the on state. The write transistor TR_(W), first transistor TR₁, and second transistor TR₂ maintain the off state. Accordingly, the first node ND₁ and the power supply line PS₁ are reconnected, and the light emitting unit ELP and driving transistor TR_(D) are also reconnected. Thus, current flows to the light emitting unit ELP, which is accordingly in lit state again.

The lit state of the light emitting unit ELP continues to a period equivalent to the end of the Period TP(1)⁻² of the next frame. Thus, the operations of emission of the display element 10 configuring the (n, m)′th sub-pixels are completed.

The length of the until period is the same, regardless of the value of m. However, the ratio of the Period TP(1)⁻¹ and Period TP(1)₂ making up the unlit periods change depending on the value of m. This holds true in the later-described other embodiments as well. For example, in the timing chart for scanning line SCL₁₅ in FIG. 4, there is no Period TP(1)⁻¹. Note that the absence of the Period TP(1)⁻¹ does not pose any problem in particular to operations of the display device.

The scan driving circuit 110 according to the first example is an integrated circuit of a structure where signals are supplied to the scanning lines SCL, initialization control line AZ, and display control line CL. Accordingly, reduction in layout area of the circuits, and reduction of circuit costs can be realized. Also, with the display device 1 according to the first embodiment, the lit/unlit state of the display elements 10 can be switched multiple times in one field period by a simple arrangement of changing the number of start pulses input to the first stage shift register making up the scan driving circuit 110, thereby reducing flickering of the image displayed on the display device.

Description will further be made with comparison to a comparative example. FIG. 13 is a circuit diagram of a scan driving circuit 120 according to a comparative example. In the scan driving circuit 120, the configuration of a logic circuit unit 122 differs from the logic circuit unit 112 of the scan driving circuit 110 according to the first embodiment. The configuration of the shift register unit 121 of the scan driving circuit 120 is the same as the shift register unit 111 of the scan driving circuit 110.

More specifically, with the scan driving circuit 120, the period identifying signal SP has been omitted, and further, the NOR circuits 114 and 115 shown in FIG. 1 have been omitted. Also, at the display element 10 to which signals based on scanning signals from a (p′, q)′th NAND circuit 123 are supplied via the scanning line SCL, signals based on the output signal ST_(p′) from the (p′)′th shift register SR_(p′) are supplied in the case of q=1, and signals based on the output signal ST_(p′+1) from the p′+1′th shift register SR_(p′+1) are supplied in the case of q>1, from the display control line CL connected to the display element 10.

With the scan driving circuit 120 of the configuration described above, the (p′, q)′th NAND circuit 123 generates scanning signals based on the output signal ST_(p), output signal ST_(p′+1), and the q′th enable signal EN_(q). Accordingly, in the event that there are multiple q′th enable signals EN_(q) in the overlapping period of the start pulse of output signal ST_(p′) and the start pulse of output signal ST_(p′+1), multiple scan signals will be generated in the overlapping period. Accordingly, if the start pulse STP is to have a leading edge between the start of the period T₁ and the end thereof, settings have to be made such that the trailing edge of the start pulse SRP is between the start and end of the period T₅. The scan driving circuit 110 according to the first embodiment does not have such restrictions.

FIG. 14 is a timing chart of the scan driving circuit 120 shown in FIG. 13 where the start pulse STP has a leading edge between the start and end of the period T₁, and a trailing edge between the start and end of the period T₅. As can be clearly seen in comparison with the timing chart in FIG. 4, similar signals as with the case in FIG. 4 are supplied to the initialization control line AZ and scanning line SCL, albeit there be phase shifting.

FIG. 15 is a timing chart regarding the scan driving circuit 120 according to the comparative example, where the first start pulse and second start pulse are input to the first stage shift register SR₁ within a period equivalent to one field period. In this case, multiple scanning signals are generated within one field period. Accordingly, with the scan driving circuit 120 according to the comparative example, there are restrictions that only one start pulse can be input to the first stage shift register SR₁, and also there are restrictions regarding the end thereof, as well. The scan driving circuit 110 according to the first embodiment has no such restrictions.

Second Embodiment

The second embodiment also relates to a scan driving circuit and to a display device having the scan driving circuit. As shown in FIG. 2, the display device 2 is of the same configuration as the display device 1 according to the first embodiment, other than the scan driving circuit being different. Accordingly, description of the display device 2 according to the second embodiment will be omitted.

FIG. 16 is a circuit diagram of a scan driving circuit according to a second embodiment, FIG. 17 is a schematic timing chart of a shift register unit making up the scan driving circuit shown in FIG. 16, FIG. 18 is a schematic timing chart of an upstream stage of a logic circuit unit 212 making up the scan driving circuit 210 shown in FIG. 16, and FIG. 19 is a schematic timing chart of a downstream stage of a logic circuit unit 212 making up the scan driving circuit 210 shown in FIG. 16.

With the scan driving circuit 110 according to the first embodiment, the first start pulse and second start pulse are input to the first stage shift register SR₁ in a period equivalent to one field period. With the scan driving circuit 210 according to the second embodiment, a third start pulse and fourth start pulse are also input in addition to these. Also, with the second embodiment, the period identifying signal is configured of a first period identifying signal SP₁ and a second period identifying signal SP₂. These are the primary points in which the second embodiment differs from the first embodiment. With the second embodiment, four periods are identified by combining the high/low level of the first period identifying signal SP₁ and second period identifying signal SP₂. Accordingly, with the second embodiment, the number of times of switching the display elements between lit/unlit states can be increased beyond that of the first embodiment.

As shown in FIG. 16, the scan driving circuit 210 also includes:

(A) a shift register unit 211 configured of P stages of shift registers SR, to sequentially shift input start pulses STP and output output signals ST from each stage; and

(B) a logic circuit unit 212 configured to operate based on output signals ST from the shift register unit 211, and enable signals (as with the first embodiment, first enable signal EN₁ and second enable signal EN₂).

With the scan driving circuit 210, the configuration of the logic circuit unit 212 differs from that of the logic circuit unit 112 of the scan driving circuit 110 according to the first embodiment. The configuration of the shift register unit 211 of the scan driving circuit 210 is the same as that of the shift register unit 111 of the scan driving circuit 110.

As mentioned above, the first start pulse through fourth start pulse are input to the first stage shift register SR₁ within a period equivalent to one field period. Specifically, as shown in FIG. 17, the first start pulse input to the first stage shift register SR₁ is a pulse having a leading edge between the start and of the period T₁ and having a trailing edge between the start and of the period T₅. The second start pulse is a pulse having a leading edge between the start and of the period T₉ and having a trailing edge between the start and of the period T₁₃. The third start pulse is a pulse having a leading edge between the start and of the period T₁₇ and having a trailing edge between the start and of the period T₂₁. The fourth start pulse is a pulse having a leading edge between the start and of the period T₂₅ and having a trailing edge between the start and of the period T₂₉.

As with the case of the first embodiment, the clock signal CK is a square wave signal which inverts polarity every two horizontal scanning periods (2H). The first start pulse in the output signal ST₁ of the shift register SR₁ has the leading edge thereof at the start of the period T₃, and has the trailing edge at the end of period T₆. The first start pulse in the output signals ST₂, ST₃, and so on, for the shift register SR₂ and subsequent shift registers is a pulse which has been sequentially shifted by two horizontal scanning periods.

Also, the second start pulse in the output signal ST₁ of the shift register SR₁ has the leading edge thereof at the start of the period T₁₁, and has the trailing edge at the end of period T₁₄. The third start pulse in the output signal ST₁ of the shift register SR₁ has the leading edge thereof at the start of the period T₁₉, and has the trailing edge at the end of period T₂₂. The fourth start pulse in the output signal ST₁ of the shift register SR₁ has the leading edge thereof at the start of the period T₂₇, and has the trailing edge at the end of period T₃₀. The second through fourth pulses in the output signals ST₂, ST₃, and so on, for the shift register SR₂ and subsequent shift registers, are also pulses which have been sequentially shifted by two horizontal scanning periods.

Also, one each of a first enable signal through a Q′th enable signal exist in sequence between the start of the first start pulse of the output signal ST_(p) and the start of the first start pulse of the output signal ST_(p+1). In the second embodiment as well, Q=2, and there are one each of the first enable signal EN₁ and the second enable signal EN₂, in sequence. The first enable signal EN₁ and the second enable signal EN₂ have been described in the first embodiment, and accordingly description thereof will be omitted here.

As shown in FIG. 16, the logic circuit unit 212 has (P−2)×Q NAND circuits 213. Specifically, the logic circuit unit 212 has (1, 1)′th through (P−2, 2)′th NAND circuits 213. Period identifying signals SP for identifying each period from the start of the u′th start pulse start pulse in an output signal ST₁ to the start of a (u+1)′th start pulse, and a period from the start of the U′th start pulse to the start of the first start pulse in the next frame, are input to the logic circuit unit 212.

In the second embodiment, U=4, and the period identifying signal SP is a signal for identifying the period from the start of the first start pulse in the output signal ST₁ to the start of the second start pulse, the period from the start of the second start pulse to the start of the third start pulse, the period from the start of the third start pulse to the start of the fourth start pulse, and the period from the start of the fourth start pulse to the start of the first start pulse in the next frame. In the second embodiment, the period identifying signal SP is configured of the first period identifying signal SP₁ and the second period identifying signal SP₂.

The first period identifying signal SP₁ is a signal which is at high level during the period from the start of period T₃ to the end of period T₁₈, and at low level during the period from the start of period T₁₉ to the end of period T₂ of the next frame. That is to say, the first period identifying signal SP₁ is the same as the period identifying signal SP in the first embodiment. Conversely, the second period identifying signal SP₂ is a signal which is at high level during the period from the start of period T₃ to the end of period T₁₀, at low level during the period from the start of period T₁₁ to the end of period T₁₈, at high level during the period from the start of period T₁₉ to the end of period T₂₆, and at low level during the period from the start of period T₂₇ to the end of period T₂ of the next frame.

With a q′th enable signal represented as EN_(q), as shown in FIG. 16 signals based on the period identifying signal SP (i.e., a signal based on the first period identifying signal SP₁ and a signal based on the second period identifying signal SP₂), the output signal ST_(p), a signal obtained by inverting the output signal ST_(p+1), and the q′th enable signal EN_(q), are input to a (p′, q)′th NAND circuit 213, whereby the operations of the NAND circuit 213 are restricted based on the first period identifying signal SP₁ and second period identifying signal SP₂, such that the NAND circuit 213 generates scanning signals based only on a portion of the output signal ST_(p′) corresponding to the first start pulse, the signal obtained by inverting the output signal ST_(p′+), and the q′th enable signal EN_(q).

The output signal ST_(p′+1) is inverted by the NOR circuit 214 shown in FIG. 16, and input to the input side of the (p′, q)′th NAND circuit 213. The output signal ST_(p′) and the q′th enable signal EN_(q) are directly input to the input side of the (p′, q)′th NAND circuit 213.

With the second embodiment, the first period identifying signal SP₁ is directly input to the input side of the (1, 1)′th through (4, 2)′th NAND circuits 213, and the second period identifying signal SP₂ is also directly input. The first period identifying signal SP₁ is directly input to the input side of the (5, 1)′th through (8, 2)′th NAND circuits 213, and the second period identifying signal SP₂ inverted by a NOR circuit 216 shown in FIG. 16 is input.

Also, the first period identifying signal SP₁ is inverted by a NOR circuit 217 shown in FIG. 16 and input to the input side of the (9, 1)′th through (12, 2)′th NAND circuits 213, and the second period identifying signal SP₂ is directly input. The first period identifying signal SP₁ is inverted by the NOR circuit 217 and input to the input side of the (13, 1)′th through (16, 2)′th NAND circuits 213, and the second period identifying signal SP₂ is inverted by the NOR circuit 216 and is input.

Let us consider the (8, 1)′th NAND circuit 213. Signals based on the scanning signals from the (8, 1)′th NAND circuit 213 are supplied to the scanning line SCL₁₄. As shown in FIG. 16, in the period T₁₇ in which the scanning signal should be generated, the output signal ST₈, the signal obtained by inverting the output signal ST₉, and the first enable signal EN₁, are at high level. However, the first stage shift register SR₁ has also received input of the second start pulse through fourth start pulse in addition to the first start pulse, so the output signal ST₈, the signal obtained by inverting the output signal ST₉, and the first enable signal EN₁, are at high level in periods T₁, T₉, and T₂₅, as well.

Accordingly, if the (8, 1)′th NAND circuit 213 were to operate based only on the output signal ST₈, a signal obtained by inverting the output signal ST₉, and the first enable signal EN₁, trouble would occur in that a scanning signal would be supplied to the scanning line SCL₁₄ not only in the period T₁₇ in which the scanning signal should be generated, but also in the periods T₁, T₉, and T₂₅. However, as described above, the first period identifying signal SP₁ is directly input to the input side of the (8, 1)′th NAND circuit 213, and the second period identifying signal SP₂ is inverted and input. In periods T₁, T₉, T₁₇, and T₂₅, the only period where the first period identifying signal SP₁ is at a high level and the second period identifying signal SP₂ is at a low level is the period T₁₇. Accordingly, the (8, 1)′th NAND circuit 213 generates a scanning signal based only on the output signal ST₈, a signal obtained by inverting the output signal ST₉, and the first enable signal EN₁.

Let us also consider the (9, 1)′th NAND circuit 213. Signals based on the scanning signals from the (9, 1)′th NAND circuit 213 are supplied to the scanning line SCL₁₆ shown in FIG. 1. As shown in FIG. 19, in the period T₁₉ in which the scanning signal should be generated, the output signal ST₉, the signal obtained by inverting the output signal ST₁₀, and the first enable signal EN₁, are at high level. However, the first stage shift register SR₁ has also received input of the second start pulse through fourth start pulse in addition to the first start pulse, so the output signal ST₉, the signal obtained by inverting the output signal ST₁₀, and the first enable signal EN₁, are at high level in periods T₃, T₁₁, and T₂₇, as well.

Accordingly, if the (9, 1)′th NAND circuit 213 were to operate based only on the output signal ST₉, a signal obtained by inverting the output signal ST₁₀, and the first enable signal EN₁, trouble would occur in that a scanning signal would be supplied to the scanning line SCL₁₆ not only in the period T₁₉ in which the scanning signal should be generated, but also in the periods T₃, T₁₁, and T₂₇. However, as described above, the first period identifying signal SP₁ is inverted and input to the (9, 1)′th NAND circuit 213, and the second period identifying signal SP₂ is directly input. In periods T₃, T₁₁, T₁₉, and T₂₇, the only period where the first period identifying signal SP₁ is at a low level and the second period identifying signal SP₂ is at a high level is the period T₁₉. Accordingly, the (9, 1)′th NAND circuit 213 generates a scanning signal based only on the output signal ST₉, a signal obtained by inverting the output signal ST₁₀, and the first enable signal EN₁.

While description has been made regarding the operations of the (8, 1)′th NAND circuit 213 and the (9, 1)′th NAND circuit 213, the operations are the same for the other NAND circuits 213 as well. The (p′, q)′th NAND circuit 213 generates a scanning signal based only on a portion of the output signal ST_(P′) corresponding to the first start pulse, the signal obtained by inverting the output signal ST_(p′+1), and the q′th enable signal EN_(q).

FIG. 20 is a schematic driving timing chart of the display element 10 at the m′th row and n′th column, corresponding to FIG. 8 in the first embodiment. In the same way as with the first embodiment, p′=8 and q=1, and m=14, when comparing the timing chart in FIG. 20 with FIGS. 17 through 19. Specifically, the timing chart of initialization control line AZ₁₄, scanning line SCL₁₄, and display control line CL₁₄ in FIG. 18 is to be referred to.

The operations of the Period TP(2)⁻² through Period TP(2)₂ shown in FIG. 20 are the same as the operations of the Period TP(1)⁻² through Period TP(1)₂ described with the first embodiment, so description thereof will be omitted. Also, Period TP(2)₉ shown in FIG. 20 corresponds to the Period TP(1)₉ described with the first embodiment, albeit there be different in the start thereof.

With the first embodiment, the lit period and unlit period switch once between the end of Period TP(1)₂ and the start Period TP(1)₅ in FIG. 8. On the other hand, with the second embodiment, the lit period and unlit period switch three times between the end of Period TP(2)₂ and the start Period TP(2)₉ in FIG. 20. Accordingly, flickering the image displayed on the display device is further reduced.

Third Embodiment

The third embodiment also relates to a scan driving circuit and to a display device having the scan driving circuit. As shown in FIG. 2, the display device 3 according to the third embodiment is of the same configuration as the display device 1 according to the first embodiment, other than the scan driving circuit being different. Accordingly, description of the display device 3 according to the third embodiment will be omitted.

FIG. 21 is a circuit diagram of a scan driving circuit 310 according to the third embodiment, FIG. 22 is a schematic timing chart of a shift register unit 311 making up the scan driving circuit 310 shown in FIG. 21, FIG. 23 is a schematic timing chart of an upstream stage of a logic circuit unit 312 making up the scan driving circuit 310 shown in FIG. 21, and FIG. 24 is a schematic timing chart of a downstream stage of the logic circuit unit 312 making up the scan driving circuit 310 shown in FIG. 21.

With the scan driving circuit 110 according to the first embodiment, a first enable signal EN₁ and second enable signal EN₂ are used. With the scan driving circuit 310 according to the third embodiment, a third enable signal EN₃ and fourth enable signal EN₄ are used in addition to these. Accordingly, the number of stages making up the shift register unit configuring the scan driving circuit can be reduced as compared with the case of the scan driving circuit 110 according to the first embodiment.

As shown in FIG. 21, the scan driving circuit 310 also includes:

(A) a shift register unit 311 configured of P stages of shift registers SR, to sequentially shift input start pulses STP and output output signals ST from each stage; and

(B) a logic circuit unit 312 configured to operate based on output signals ST from the shift register unit 311, and enable signals (in the case of the third embodiment, first enable signal EN₁, second enable signal EN₂, third enable signal EN₃, and fourth enable signal EN₄).

Representing the output signals of the p′th stage shift register SR_(p) with ST_(p), the start of the start pulse in the output signal ST_(p+1) of the p+1′th stage shift register SR_(p+1) is situated between the start and end of the start pulse in the output signal ST_(p), as shown in FIG. 22. The shift register unit 311 operates based on the clock signals CK and start pulse STP so as to satisfy the above conditions.

A first start pulse through a U′th start pulse are input to the first stage shift register SR₁ in a period equivalent to one field period. Note that with the third embodiment, U=2 the same as with the first embodiment, and the first start pulse and second start pulse are input.

Specifically, the first start pulse input to the first stage shift register SR₁ is a pulse which has a leading edge between the start and end of the period T₁ shown in FIG. 22, and which has a trailing edge between the start and end of the period T₉. Also, the second start pulse is a pulse which has a leading edge between the start and end of the period T₁₇ shown in FIG. 22, and which has a trailing edge between the start and end of the period T₂₅.

With the first and second embodiments, the clock signal CK is a square wave signal of which the polarity inverts every two horizontal scanning periods. Conversely, with the third embodiment, the clock signal CK is a square wave signal of which the polarity inverts every four horizontal scanning periods.

The first start pulse in the output signal ST₁ of the shift register SR₁ is a pulse which has the leading edge thereof at the start of the period T₃, and has the trailing edge at the end of period T₁₀. The first start pulses in the output signals ST₂, ST₃, and so on, for the shift register SR₂ and subsequent shift registers, are pulses which have been sequentially shifted by four horizontal scanning periods. The second start pulse in the output signal ST₁ of the shift register SR₁ is a pulse which has the leading edge thereof at the start of the period T₁₉, and has the trailing edge at the end of period T₂₆. The second start pulses in the output signals ST₂, ST₃, and so on, for the shift register SR₂ and subsequent shift registers, are pulses which have been sequentially shifted by four horizontal scanning periods.

Also, one each of a first enable signal through a Q′th enable signal exist in sequence between the start of the first start pulse of the output signal ST_(p) and the start of the first start pulse of the output signal ST_(p+1). In the third embodiment, Q=4, and there are one each of the first enable signal EN₁, second enable signal EN₂, third enable signal EN₃, and fourth enable signal EN₄ in sequence. In other words, the first enable signal EN₁, second enable signal EN₂, third enable signal EN₃, and fourth enable signal EN₄ are signals generated so as to satisfy the above conditions, and basically are square wave signals of the same cycle but with different phases.

Specifically, the first enable signal EN₁ is a square wave signal of which one cycle is four horizontal scanning periods. The second enable signal EN₂ is a signal of which the phase is delayed as to the first enable signal EN₁ by one horizontal scanning period. The third enable signal EN₃ is a signal of which the phase is delayed as to the first enable signal EN₁ by two horizontal scanning periods. The fourth enable signal EN₄ is a signal of which the phase is delayed as to the first enable signal EN₁ by three horizontal scanning periods.

For example, one each of the first enable signal EN₁ in the period T₃, the second enable signal EN₂ in the period T₄, the third enable signal EN₃ in the period T₅, and the fourth enable signal EN₄ in the period T₆, sequentially exist between the start of the start pulse in the output signal ST₁ (i.e., start of period T₃) and the start of the start pulse in the output signal ST₂ (i.e., start of period T₇). In the same way, one each of the first enable signal EN₁, second enable signal EN₂, third enable signal EN₃, and fourth enable signal EN₄, serially exist between the start of the start pulse in the output signal ST₂ and the start of the start pulse in the output signal ST₃.

As shown in FIG. 21, the logic circuit unit 312 has (P−2)×Q NAND circuits 313. Specifically, the logic circuit unit 312 has (1, 1)′th through (P−2, 4)′th NAND circuits 313. Period identifying signals SP for identifying each period from the start of the u′th start pulse start pulse in an output signal ST₁ to the start of a (u+1)′th start pulse, and a period from the start of the U′th start pulse to the start of the first start pulse in the next frame, are input to the logic circuit unit 312.

In the third embodiment, U=2, and the period identifying signal SP is as described with the first embodiment. That is to say, the period identifying signal SP is a signal for identifying the period from the start of the first start pulse in the output signal ST₁ to the start of the second start pulse, and the period from the start of the second start pulse to the start of the first start pulse in the next frame. In the third embodiment as well, the period identifying signal SP is a signal which is at high level during the period from the start of period T₃ to the end of period T₁₈, and at low level during the period from the start of period T₁₉ to the end of period T₂ of the next frame.

With a q′th enable signal represented as EN_(q), as shown in FIG. 21 signals based on the period identifying signal SP, the output signal ST_(p), a signal obtained by inverting the output signal ST_(p+1), and the q′th enable signal EN_(q), are input to a (p′, q)′th NAND circuit 313, whereby the operations of the NAND circuit 313 are restricted based on the period identifying signal SP, such that the NAND circuit 313 generates scanning signals based only on a portion of the output signal ST_(p′) corresponding to the first start pulse, the signal obtained by inverting the output signal ST_(p′+1), and the q′th enable signal EN_(q).

The output signal ST_(p′+1) is inverted by the NOR circuit 314 shown in FIG. 21, and input to the input side of the (p′, q)′th NAND circuit 313. The output signal ST_(p′) and the q′th enable signal EN_(q) are directly input to the input side of the (p′, q)′th NAND circuit 313.

With the third embodiment, as with the first embodiment, the period identifying signal SP is directly input to the input side of the (1, 1)′th through (4, 4)′th NAND circuits 313. The period identifying signal SP is inverted by the NOR circuit 316 and input to the input side of the (5, 1)′th through (8, 4)′th NAND circuits 313.

Let us consider the (4, 3)′th NAND circuit 313, for example. Signals based on the scanning signals from the (4, 3)′th NAND circuit 313 are supplied to the scanning line SCL₁₄ shown in FIG. 21. As shown in FIG. 23, in the period T₁₇ in which the scanning signal should be generated, the output signal ST₄, the signal obtained by inverting the output signal ST₅, and the third enable signal EN₃, are at high level. However, the first stage shift register SR₁ has also received input of the second start pulse in addition to the first start pulse, so the output signal ST₄, the signal obtained by inverting the output signal ST₅, and the third enable signal EN₃, are at high level in period T₁ as well.

Accordingly, if the (4, 3)′th NAND circuit 313 were to operate based only on the output signal ST₄, a signal obtained by inverting the output signal ST₅, and the third enable signal EN₃, trouble would occur in that a scanning signal would be supplied to the scanning line SCL₁₄ not only in the period T₁₇ in which the scanning signal should be generated, but also in the period T₁. However, as described above, the period identifying signal SP is directly input to the input side of the (4, 3)′th NAND circuit 313. Of periods T₁ and T₁₇, the only period where the period identifying signal SP is at a high level is the period T₁₇. Accordingly, the (4, 3)′th NAND circuit 313 generates a scanning signal based only on the output signal ST₄, a signal obtained by inverting the output signal ST₅, and the third enable signal EN₃.

Let us also consider the (5, 1)′th NAND circuit 313. Signals based on the scanning signals from the (5, 1)′th NAND circuit 313 are supplied to the scanning line SCL₁₆ shown in FIG. 21. As shown in FIG. 24, in the period T₁₉ in which the scanning signal should be generated, the output signal ST₅, the signal obtained by inverting the output signal ST₆, and the first enable signal EN₁, are at high level. However, the first stage shift register SR₁ has also received input of the second start pulse in addition to the first start pulse, so the output signal ST₅, the signal obtained by inverting the output signal ST₆, and the first enable signal EN₁, are at high level in period T₃ as well.

Accordingly, if the (5, 1)′th NAND circuit 313 were to operate based only on the output signal ST₅, a signal obtained by inverting the output signal ST₆, and the first enable signal EN₁, trouble would occur in that a scanning signal would be supplied to the scanning line SCL₁₆ not only in the period T₁₉ in which the scanning signal should be generated, but also in the period T₃. However, as described above, the period identifying signal SP is inverted and input to the (5, 1)′th NAND circuit 313. Of periods T₃ and T₁₉, the only period where the period identifying signal SP is at a low level is the period T₁₉. Accordingly, the (5, 1)′th NAND circuit 313 generates a scanning signal based only on the output signal ST₅, a signal obtained by inverting the output signal ST₆, and the first enable signal EN₁.

While description has been made regarding the operations of the (4, 3)′th NAND circuit 313 and the (5, 1)′th NAND circuit 313, the operations are the same for the other NAND circuits 313 as well. The (p′, q)′th NAND circuit 313 generates a scanning signal based only on a portion of the output signal ST_(p′) corresponding to the first start pulse in the output signal ST_(p′), the signal obtained by inverting the output signal ST_(p′+1), and the q′th enable signal EN_(q).

FIG. 25 is a schematic driving timing chart of the display element 10 at the m′th row and n′th column, corresponding to FIG. 8 in the first embodiment. Here, p′=4 and q=3, and in the same way as with the first embodiment, m=14, when comparing the timing chart in FIG. 25 with FIGS. 22 through 24. Specifically, the timing chart of initialization control line AZ₁₄, scanning line SCL₁₄, and display control line CL₁₄ in FIG. 23 is to be referred to.

The operations of the Period TP(3)⁻² through Period TP(3)₂ shown in FIG. 25 are the same as the operations of the Period TP(1)⁻² through Period TP(1)₂ described with the first embodiment, so description thereof will be omitted. Also, the operations of Period TP(3)₃ through Period TP(3)₅ shown in FIG. 25 are the same as the operations of Period TP(1)₃ through Period TP(1)₅ described with the first embodiment, albeit there be different in the length of periods thereof, so description thereof will be omitted.

While the present invention has been described so far with reference to preferred embodiments, the present invention is not restricted by these embodiments. The configuration and structure of the various components configuring the scan driving circuit, display device, and display elements, and the processes in the operations of the display device, described in the embodiments, may be modified as appropriate.

For example, with the driving circuit 11 configuring the display element 10 shown in FIG. 6, in the event that the third transistor TR₃ and fourth transistor TR₄ are n-channel type transistors, the NOR circuit 115 shown in FIG. 1, the NOR circuit 215 shown in FIG. 16, and the NOR circuit 315 shown in FIG. 21, can be omitted. In this way, the polarity of signals from the scan driving circuit can be suitably set in accordance with the configuration of the display elements, and supplied to the scanning lines, initialization control lines, and display control lines.

The present application contains subject matter related to that disclosed in Japanese Priority Patent Application JP 2008-182369 filed in the Japan Patent Office on Jul. 14, 2008, the entire content of which is hereby incorporated by reference.

It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and alterations may occur depending on design requirements and other factors insofar as they are within the scope of the appended claims or the equivalents thereof. 

1-38. (canceled)
 39. A display apparatus comprising: a plurality of pixel circuits respectively including a light emitting device, a first transistor, a second transistor, a first switch circuit, a second switch circuit, a third switch circuit, a fourth switch circuit, and a capacitor, wherein the first transistor is connected between a signal line and one drain/source of the second transistor, wherein the first switch circuit is connected between the other drain/source of the second transistor and a gate of the second transistor, wherein the second switch circuit is connected between a first voltage line and the gate of the second transistor, wherein the third switch circuit is connected between a second voltage line and the one drain/source of the second transistor, wherein the fourth switch circuit is connected between the other drain/source of the second transistor and the light emitting device, wherein the light emitting device has an anode electrode, a light emitting layer, and a cathode electrode, wherein the light emitting device is provided on a first insulation layer covering the plurality of pixel circuits, wherein the cathode electrode is provided on a second insulation layer which is arranged on the first insulation layer, wherein the cathode electrode is connected to a third voltage line, wherein the second switch circuit is configured to propagate a first voltage from the first voltage line to the gate of the second transistor according to a first scan signal, wherein the first transistor is configured to propagate a data voltage from the signal line to the one drain/source of the second transistor according to a second scan signal, wherein the third transistor is configured to propagate a second voltage from the second voltage line to the one drain/source of the second transistor according to a third scan signal, wherein the second scan signal is supplied from a first side of the plurality of pixel circuits, and wherein the third scan signal is supplied from the first side of the plurality of pixel circuits.
 40. The display apparatus according to claim 39, wherein the second switch circuit is configured to propagate the first voltage from the first voltage line to the gate of the second transistor during a first period.
 41. The display apparatus according to claim 40, wherein the first transistor is configured to propagate a data voltage from the signal line to the one drain/source of the second transistor.
 42. The display apparatus according to claim 39, wherein the second switch circuit is configured to propagate the first voltage from the first voltage line to the gate of the second transistor during a first period, wherein the first transistor is configured to propagate a data voltage from the signal line to the one drain/source of the second transistor during a second period after the first period, and wherein the third transistor is configured to propagate the second voltage from the second voltage line to the one drain/source of the second transistor during a third period after the second period.
 43. The display apparatus according to claim 39, wherein the light emitting device is configured to emit light at least two times in one field period.
 44. The display apparatus according to claim 39, wherein the light emitting device is configured to emit light at least four times in one field period.
 45. The display apparatus according to claim 39, further comprising a driving circuit comprising a shift register unit and a logic circuit unit.
 46. The display apparatus according to claim 45, wherein the driving circuit is configured to supply the first scan signal, the second scan signal, and the third scan signal.
 47. The display apparatus according to claim 39, wherein the first scan signal is supplied from the first side of the plurality of pixel circuits. 